% "The meshes were generated using Cubit 14.1 ... and optimized with libMesh ..."
@phdthesis{VilladaGil_thesis,
  author = {Stiven {Villada Gil}},
  school = {Universidad Nacional de Colombia},
  title  = {Dynamics of confined liquid crystals},
  note   = {\url{https://repositorio.unal.edu.co/handle/unal/79330}},
  month  = sep,
  year   = 2020
}

% MARMOT/phase_field
% Link to the book: https://www.springer.com/us/book/9783319446790
% Link to the chapter: https://www.researchgate.net/publication/326635622_Phase_Field_Modeling_of_Microstructure_Evolution_in_Nuclear_Materials
@InCollection{Ahmed_2020,
  author    = {Karim Ahmed and Anter {El-Azab}},
  title     = {{Phase Field Modeling of Microstructure Evolution in Nuclear Materials}},
  pages     = {2313--2334},
  publisher = {Springer},
  year      = 2020,
  editor    = {W. Andreoni and S. Yip},
  booktitle = {Handbook of Materials Modeling, Applications: Current and Emerging Materials},
  note      = {\url{https://doi.org/10.1007/978-3-319-44680-6_133}}
}

% MOOSE/BISON
% http://kyt2022.vtt.fi/raportit_2020/PORA_BISON%20mesh%20generation%20script%20for%20analysis%20of%20cracked%20fuel%20pellets.pdf
@TechReport{Peltonen_2020,
  author      = {Jussi Peltonen},
  title       = {{BISON mesh generation script for analysis of cracked fuel pellets}},
  institution = {VTT Technical Research Centre of Finland},
  day         = 17,
  month       = nov,
  year        = 2020,
  number      = {VTT-R-01544-20},
  note        = {\url{https://tinyurl.com/wwtf9mfw}}
}

% MOOSE
% "Time evolution of the system was performed according to the Cahn-Hilliard
% equation using the MOOSE ... framework"
@Article{Aparicio_2020,
  author  = {Emiliano Aparicio and Emmanuel N. Mill{\'{a}}n and Carlos J. Ruestes and Eduardo M. Bringa},
  title   = {{FoamExplorer: Automated measurement of ligaments and voids for atomistic systems}},
  journal = {Computational Materials Science},
  month   = dec,
  year    = 2020,
  volume  = 185,
  pages   = {109942 (10 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2020.109942}}
}

% MOOSE/Rattlesnake
@Article{Prince_2020c,
  author  = {Zachary Prince and Yaqi Wang and Logan Harbour},
  title   = {{A diffusion synthetic acceleration approach to $k$-eigenvalue neutron transport using PJFNK}},
  journal = {Annals of Nuclear Energy},
  month   = dec,
  year    = 2020,
  volume  = 148,
  pages   = {107714 (11 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2020.107714}}
}

% MOOSE/Moltres
@mastersthesis{Lee_thesis,
  author = {Alvin J. H. Lee},
  school = {University of Illinois at Urbana-Champaign},
  title  = {{Neutronics and thermal-hydraulics analysis of transatomic power molten salt reactor (TAP MSR) core under load following operations}},
  note   = {\url{http://hdl.handle.net/2142/109415}},
  month  = dec,
  year   = 2020
}

% MOOSE/Moltres
@mastersthesis{Agosta_thesis,
  author = {Roberto E. Fairhurst Agosta},
  school = {University of Illinois at Urbana-Champaign},
  title  = {Multi-physics and technical analysis of high-temperature gas-cooled reactors for hydrogen production},
  note   = {\url{http://hdl.handle.net/2142/109439}},
  month  = dec,
  year   = 2020
}

% MOOSE
% "Simulations of the system behavior are conducted in MOOSE"
@Article{Vogler_2020b,
  author  = {Daniel Vogler and Stuart D. C. Walsh and Martin O. Saar},
  title   = {A numerical investigation into key factors controlling hard rock excavation via electropulse stimulation},
  journal = {Journal of Rock Mechanics and Geotechnical Engineering},
  month   = aug,
  year    = 2020,
  volume  = 12,
  number  = 4,
  pages   = {793--801},
  note    = {\url{https://doi.org/10.1016/j.jrmge.2020.02.002}}
}

% MOOSE/ray tracing
@phdthesis{Gaston_thesis,
  author = {Derek Ray Gaston},
  school = {Massachusetts Institute of Technology},
  title  = {{Parallel, asynchronous ray-tracing for scalable, 3D, full-core method of characteristics neutron transport on unstructured mesh}},
  note   = {\url{https://hdl.handle.net/1721.1/129911}},
  month  = feb,
  year   = 2020
}

% MOOSE
@Article{Saklani_2020c,
  author  = {N. Saklani and B. M. Khaled and G. Banwat and B. Spencer and A. Giorla and G. Sant and S. Rajan and N. Neithalath},
  title   = {{Implementation of creep-damage model for concrete fracture in MOOSE}},
  journal = {ACI Materials Journal},
  month   = nov,
  year    = 2020,
  volume  = 117,
  number  = 6,
  pages   = {135--149},
  note    = {\url{https://doi.org/10.14359/51729312}}
}

% MOOSE
@mastersthesis{Franklin_thesis,
  author = {Andrew M. Franklin},
  school = {Texas A\&M University},
  title  = {{An implementation of surface-to-surface, blackbody radiation heat transfer in a MOOSE application}},
  note   = {\url{https://hdl.handle.net/1969.1/192275}},
  month  = aug,
  year   = 2020
}

% MOOSE
@InProceedings{Balestra_2020b,
  author    = {Paolo Balestra and Abdalla Abou-Jaoude and Sebastian Schunert and Andrew Hermosillo and Yaqi Wang and Nicolas P. Martin},
  title     = {{Coupled multiphysics simulation of pool-type molten salt reactors using Griffin/Pronghorn}},
  booktitle = {{Transactions of the American Nuclear Society, Vol.~123}},
  address   = {Virtual, Online},
  pages     = {1587--1590},
  month     = nov,
  year      = 2020,
  note      = {\url{https://doi.org/10.13182/T123-33466}}
}

% MOOSE
% "The model is implemented in the finite element environment MOOSE "
@phdthesis{ZZhou_2020,
  author = {Ziqi Zhou},
  school = {Technische Universit{\"{a}}t, Darmstadt},
  title  = {Microscopic simulation of the mechanically modulated electrical conductivity of piezoelectric semiconductors},
  note   = {\url{https://doi.org/10.26083/tuprints-00014273}},
  month  = sep,
  year   = 2020
}

% MOOSE
% Doesn't use MOOSE but contains a very extensive description of how MOOSE could be used in a project
@TechReport{Wozniak_2020,
  author      = {Nicholas Wozniak and Emily R. Shemon and James J. Grudzinski},
  title       = {Review of tools for modeling core radial expansion in liquid metal-cooled fast reactors},
  institution = {Argonne National Laboratory},
  day         = 30,
  month       = nov,
  year        = 2020,
  number      = {ANL/NSE-20/41},
  note        = {\url{https://doi.org/10.2172/1755931}}
}

% MOOSE/phase_field
% "Phase-field based numerical simulations were performed using the software package MOOSE"
% https://indigo.uic.edu/articles/thesis/Directing_the_Complex_Behavior_of_Metal_Anodes_Using_Two_Dimensional_Materials/13475478/1
@phdthesis{Foroozan_thesis,
  author = {Tara Foroozan},
  school = {University of Illinois at Chicago},
  title  = {Directing the complex behavior of metal anodes using two dimensional materials},
  note   = {\url{https://doi.org/10.25417/uic.13475478.v1}},
  month  = jul,
  year   = 2020
}

% BISON
@TechReport{Yushu_2020,
  author      = {D. Yushu and S. A. Pitts and D. vanWasshenova and A. Recuero and D. J. McDowell and A. D. Lindsay and B. W. Spencer and D. Schwen},
  title       = {{Summary of Bison documentation and UX milestones -- NEAMS FY20 Report}},
  institution = {Idaho National Laboratory},
  day         = 31,
  month       = oct,
  year        = 2020,
  number      = {INL/EXT-20-59954},
  note        = {\url{https://doi.org/10.2172/1734544}}
}

% MOOSE/BISON
% https://search.proquest.com/openview/22d5bf392f41dbb27c19d0ee697608d0/1?pq-origsite=gscholar&cbl=18750&diss=y
@phdthesis{Cheniour_thesis,
  author = {Amani Cheniour},
  school = {University of Florida},
  title  = {{Study of U$_3$Si$_2$ fuel microstructure behavior under LWR conditions using the phase field method}},
  note   = {\url{https://tinyurl.com/ybzelt4n}},
  month  = may,
  year   = 2020
}

% MOOSE
% "The finite element modeling framework MOOSE is used to solve the coupled model."
@Article{YiZhang_2020,
  author  = {Yi Zhang and Xinglin Lei and Tsutomu Hashimoto and Ziqiu Xue},
  title   = {In situ hydromechanical responses during well drilling recorded by fiber-optic distributed strain sensing},
  journal = {Solid Earth},
  month   = dec,
  year    = 2020,
  volume  = 11,
  number  = 6,
  pages   = {2487--2497},
  note    = {\url{https://doi.org/10.5194/se-11-2487-2020}}
}

% MOOSE/Moltres
% "The fully coupled system is implemented and solved in MOOSE"
% https://ir.library.oregonstate.edu/concern/graduate_thesis_or_dissertations/f1881t34d
@phdthesis{Reynolds_thesis,
  author = {Aaron James Reynolds},
  school = {Oregon State University},
  title  = {A multilevel nonlinear projective method for circulating fuel reactor kinetics},
  note   = {\url{https://tinyurl.com/y9x73rjn}},
  month  = nov,
  year   = 2020
}

% MOOSE/TIGER
% "The open-source code TIGER ... has been ... implemented within ... MOOSE"
@Article{Stricker_2020,
  author  = {Kai Stricker and Jens C. Grimmer and Robert Egert and Judith Bremer and Maziar Gholami Korzani and Eva Schill and Thomas Kohl},
  title   = {The potential of depleted oil reservoirs for high-temperature storage systems},
  journal = {Energies},
  month   = dec,
  year    = 2020,
  volume  = 13,
  number  = 24,
  pages   = {6510 (27 pages)},
  note    = {\url{https://doi.org/10.3390/en13246510}}
}

% MOOSE
% "PorousFlow is built upon the open-source, massively parallel, fully implicit multiphysics simulation framework MOOSE"
@Article{Wilkins_2020c,
  author  = {Andy Wilkins and Christopher P. Green and Jonathan Ennis-King},
  title   = {{PorousFlow: A multiphysics simulation code for coupled problems in porous media}},
  journal = {Journal of Open Source Software},
  month   = nov,
  year    = 2020,
  volume  = 5,
  number  = 55,
  pages   = {2176 (6 pages)},
  note    = {\url{https://doi.org/10.21105/joss.02176}}
}

% Akselos
% "The degrees of freedom of the full model exceed four million in the original
% finite element model which is solved by the SCRBE solver from Akselos"
@Article{Bigoni_2020,
  author  = {Caterina Bigoni and Zhenying Zhang and Jan S. Hesthaven},
  title   = {Systematic sensor placement for structural anomaly detection in the absence of damaged states},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = nov,
  year    = 2020,
  volume  = 371,
  pages   = {113315 (26 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2020.113315}}
}

% Akselos
% "We restrict the nonlinearities in this work to be the plasticity that occurs locally with linear
% isotropic hardening, solved by the hybrid-SCRBE solver from Akselos [60] as the "truth" solutions."
@Article{ZZhang_2020,
  author  = {Zhenying Zhang and Jan S. Hesthaven},
  title   = {{Rare event simulation for large-scale structures with local nonlinearities}},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = jul,
  year    = 2020,
  volume  = 366,
  pages   = {113051 (34 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2020.113051}}
}

% Akselos
% "We present a structural digital twin system based on ... (RB-FEA) framework."
@InProceedings{Podskarbi_2020,
  author    = {Mat Podskarbi and David J. Knezevic},
  title     = {{Digital Twin for operations -- Present applications and future digital thread}},
  booktitle = {{Proceedings of the Offshore Technology Conference}},
  address   = {Houston, Texas},
  pages     = {OTC-30553-MS (13 pages)},
  month     = may # {~4--7,},
  year      = 2020,
  note      = {\url{https://doi.org/10.4043/30553-MS}}
}

% SCRBE
% "To this end, a component-based reduced-order model for the UAV has been
% developed using the Akselos Integra modeling software, in collaboration with Akselos Inc"
@InProceedings{Kapteyn_2020,
  author    = {Michael G. Kapteyn and David J. Knezevic and Karen E. Willcox},
  title     = {{Toward predictive digital twins via component-based reduced-order models and interpretable machine learning}},
  booktitle = {{Proceedings of the AIAA 2020 Science and Technology Forum and Exposition}},
  address   = {Orlando, Florida},
  pages     = {AIAA-2020-0418 (19 pages)},
  month     = jan # {~6--10,},
  year      = 2020,
  note      = {\url{https://doi.org/10.2514/6.2020-0418}, Winner of MDO Best Paper Award}
}

% MOOSE/DireWolf
% https://gain.inl.gov/MicroreactorProgramTechnicalReports/Document-INL-EXT-20-59691.pdf
@TechReport{Lange_2020,
  author      = {Travis Lange},
  title       = {{Experience with DireWolf for heat-pipe microreactor analysis to support early demonstration}},
  institution = {Idaho National Laboratory},
  month       = jun,
  year        = 2020,
  number      = {INL/EXT-20-59691},
  note        = {\url{https://tinyurl.com/y3rw6zp9}}
}

% MOOSE/BISON
% "... in this work, a demonstration is performed using the finite element-based nuclear fuel performance code BISON"
@Article{Toptan_2020c,
  author  = {Aysenur Toptan and Nathan Porter and Jason D. Hales and Benjamin W. Spencer and Martin Pilch and Richard L. Williamson},
  title   = {Construction of a code verification matrix for heat conduction with finite element code applications},
  journal = {Journal of Verification, Validation and Uncertainty Quantification},
  month   = dec,
  year    = 2020,
  volume  = 5,
  number  = 4,
  pages   = {041002 (15 pages)},
  note    = {Paper No.\ VVUQ-20-1032, \url{https://doi.org/10.1115/1.4049037}}
}

% MOOSE/REDBACK
% "The different systems of equations are solved with REDBACK ... based on ... (MOOSE)"
% https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/65/e3sconf_icegt2020_03002.pdf
@InProceedings{Lesueur_2020e,
  author    = {Martin Lesueur and Thomas Poulet and Manolis Veveakis},
  title     = {Fault reactivation during fluid production, modelled as a multiphysics multi-scale instability},
  booktitle = {{Proceedings of the 2nd International Conference on Energy Geotechnics (ICEGT 2020)}},
  address   = {La Jolla, California},
  pages     = {03002 (6 pages)},
  month     = nov,
  year      = 2020,
  note      = {\url{https://doi.org/10.1051/e3sconf/202020503002}, Conference postponed until April 2022}
}

% MOOSE/BISON
@TechReport{Hales_2020b,
  author      = {Jason D. Hales and Wen Jiang and Aysenur Toptan and Kyle A. Gamble},
  title       = {{BISON TRISO modeling advancements and validation to AGR-1 data}},
  institution = {Idaho National Laboratory},
  day         = 14,
  month       = sep,
  year        = 2020,
  number      = {INL/EXT-20-59368},
  note        = {\url{https://doi.org/10.2172/1711423}}
}

% libMesh
% "We implement the whole model in libMesh, ..."
% https://www.researchgate.net/publication/346039558_Simulation_of_a_drop_impact_on_a_moving_wall_with_a_liquid_film_using_the_convected_level-set_method
@InProceedings{Grave_2020e,
  author    = {Mal{\'{u}} Grave and Jose J. Camata and Alvaro L. G. A. Coutinho},
  title     = {Simulation of a drop impact on a moving wall with a liquid film using the convected level-set method},
  booktitle = {{Proceedings of the XLI Ibero-Latin American Conference on Computational Methods in Engineering (CILAMCE 2020)}},
  address   = {Foz do Igua{\c{c}}u, Paran{\'{a}}, Brazil},
  month     = nov # {~16--19,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/y3xtw9gv}}
}

% libMesh
% "We implement the mathematical model in libMesh..."
% https://www.researchgate.net/publication/346039553_Numerical_modeling_of_venting_of_particle-driven_gravity_currents_in_reser-_voirs
@InProceedings{Grave_2020d,
  author    = {Mal{\'{u}} Grave and Jose J. Camata and Alvaro L. G. A. Coutinho},
  title     = {Numerical modeling of venting of particle-driven gravity currents in reservoirs},
  booktitle = {{Proceedings of the XLI Ibero-Latin American Conference on Computational Methods in Engineering (CILAMCE 2020)}},
  address   = {Foz do Igua{\c{c}}u, Paran{\'{a}}, Brazil},
  month     = nov # {~16--19,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/y5o4htlk}}
}

% MOOSE
% "All numerical tests have been implemented in "Parrot" ... in the FE framework MOOSE"
% author:nestola author:favino discrete maximum principle
@Misc{Nestola_2020,
  author       = {Maria Giuseppina Chiara Nestola and Marco Favino},
  title        = {A novel equi-dimensional finite element method for flow and transport in fractured porous media satisfying discrete maximum principle and conservation properties},
  month        = nov,
  year         = 2020,
  howpublished = {ArXiv e-print},
  note         = {\url{https://arxiv.org/abs/2011.08804}}
}

% MOOSE/Rattlesnake
% https://www.researchgate.net/publication/331670661_A_highly_parallel_multilevel_Newton-Krylov-Schwarz_method_with_subspace-based_coarsening_and_partition-based_balancing_for_the_multigroup_neutron_transport_equations_on_3D_unstructured_meshes
@Article{Kong_2020b,
  author  = {Fande Kong and Yaqi Wang and Derek R. Gaston and Cody J. Permann and Andrew E. Slaughter and Alexander D. Lindsay and Mark D. DeHart and Richard C. Martineau},
  title   = {{A highly parallel multilevel Newton--Krylov--Schwarz method with subspace-based coarsening and partition-based balancing for the multigroup neutron transport equations on 3D unstructured meshes}},
  journal = {SIAM Journal on Scientific Computing},
  year    = 2020,
  volume  = 42,
  number  = 5,
  pages   = {C193--C220},
  note    = {\url{https://doi.org/10.1137/19M1249060}, ArXiv e-print: \url{https://arxiv.org/abs/1903.03659}}
}

% MOOSE
% "We developed a continuum model to describe the coupled physics of reduced-order chemistry and thermal
% transport and implemented them in the MOOSE simulation framework"
@Article{Sakano_2020,
  author  = {Michael N. Sakano and Ahmed Hamed and Edward M. Kober and Nicolo Grilli and Brenden W. Hamilton and Md Mahbubul Islam and Marisol Koslowski and Alejandro Strachan},
  title   = {{Unsupervised learning-based multiscale model of thermochemistry in 1,3,5-Trinitro-1,3,5-triazinane (RDX)}},
  journal = {The Journal of Physical Chemistry A},
  month   = nov,
  year    = 2020,
  volume  = 124,
  number  = 44,
  pages   = {9141--9155},
  note    = {\url{https://doi.org/10.1021/acs.jpca.0c07320}}
}

% MOOSE
% "In addition, several POD-RB ROM capabilities have been added to the MOOSE framework"
@Article{German_2020,
  author  = {P{\'{e}}ter German and Mauricio Tano and Jean C. Ragusa and Carlo Fiorina},
  title   = {{Comparison of Reduced-Basis techniques for the model order reduction of parametric incompressible fluid flows}},
  journal = {Progress in Nuclear Energy},
  month   = dec,
  year    = 2020,
  volume  = 130,
  pages   = {103551 (19 pages)},
  note    = {\url{https://doi.org/10.1016/j.pnucene.2020.103551}}
}

% MOOSE/DG-OSPREY
% "DG-OSPREY is ... built within ... MOOSE"
@Article{Wiechert_2020,
  author  = {Alexander I. Wiechert and Austin P. Ladshaw and Jisue Moon and Carter W. Abney and Yue Nan and Seungrag Choi and Jiuxu Liu and Lawrence L. Tavlarides and Costas Tsouris and Sotira Yiacoumi},
  title   = {{Capture of iodine from nuclear-fuel-reprocessing off-gas: Influence of aging on a reduced silver mordenite adsorbent after exposure to NO/NO$_2$}},
  journal = {ACS Applied Materials \& Interfaces},
  month   = nov,
  year    = 2020,
  volume  = 12,
  number  = 44,
  pages   = {49680--49693},
  note    = {\url{https://doi.org/10.1021/acsami.0c15456}}
}

% MOOSE/phase_field
% "Here we use the fully open source MOOSE (Multiphysics Object-Oriented
% Simulation Environment) framework (54) to solve the phase-field equations (55)."
@Article{Ahmad_2020,
  author  = {Zeeshan Ahmad and Zijian Hong and Venkatasubramanian Viswanathan},
  title   = {Design rules for liquid crystalline electrolytes for enabling dendrite-free lithium metal batteries},
  journal = {Proceedings of the National Academy of Sciences},
  month   = oct,
  year    = 2020,
  volume  = 117,
  number  = 43,
  pages   = {26672--26680},
  note    = {\url{https://doi.org/10.1073/pnas.2008841117}, ArXiv e-print: \url{https://arxiv.org/abs/1907.04441}}
}

% MOOSE/Redback
% "The system of equations ... is implemented and solved numerically using ... MOOSE"
@Article{Guevel_2020,
  author  = {A. Gu{\'{e}}vel and H. Rattez and E. Veveakis},
  title   = {{Viscous phase-field modeling for chemo-mechanical microstructural evolution: Application to geomaterials and pressure solution}},
  journal = {International Journal of Solids and Structures},
  month   = dec,
  year    = 2020,
  volume  = 207,
  pages   = {230--249},
  note    = {\url{https://doi.org/10.1016/j.ijsolstr.2020.09.026}}
}

% MOOSE
% "FECD has been implemented in a new cluster dynamics code Centipede which is built on the MOOSE framework"
% https://www.osti.gov/biblio/1645086
@Article{Matthews_2020,
  author  = {Christopher Matthews and Romain Perriot and Michael M. D. Cooper and Christopher R. Stanek and David A. Andersson},
  title   = {{Cluster dynamics simulation of xenon diffusion during irradiation in UO$_2$}},
  journal = {Journal of Nuclear Materials},
  month   = nov,
  year    = 2020,
  volume  = 540,
  pages   = {152326 (14 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152326}}
}

% MOOSE/BISON
% "In this work, finite element analysis was performed using BISON..."
% https://tcr.ornl.gov/wp-content/uploads/2020/10/M2TC-20OR0406015_V2.pdf
@TechReport{XHu_2020,
  author      = {Xunxiang Hu and Danny Schappel and Artem A. Trofimov and Hsin Wang and Ying Yang and Chinthaka M. Silva and Mehdi Balooch and Kurt A. Terrani},
  title       = {Physical and thermomechanical properties of yttrium hydride from large scale bulk metal hydriding furnace},
  institution = {Oak Ridge National Laboratory},
  month       = sep,
  year        = 2020,
  number      = {ORNL/TM-2020/1659},
  note        = {\url{https://tinyurl.com/yx9bcucu}}
}

% libMesh
% "The framework's implementation sits on top of the parallel finite element library libMesh ..."
@Article{SalazardeTroya_2020,
  author  = {Miguel A. {Salazar de Troya} and Daniel A. Tortorelli},
  title   = {{Three-dimensional adaptive mesh refinement in stress-constrained topology optimization}},
  journal = {Structural and Multidisciplinary Optimization},
  month   = nov,
  year    = 2020,
  volume  = 62,
  number  = 5,
  pages   = {2467--2479},
  note    = {\url{https://doi.org/10.1007/s00158-020-02618-z}}
}

% MOOSE/CATS
% "Simulations for NH3 transients and storage is part of a coding project called CATS ... built on the MOOSE framework"
% https://cleers.org/wp-content/uploads/formidable/3/2020CLEERS_Ladshaw_Web.pdf
@InProceedings{Ladshaw_2020,
  author    = {Austin Ladshaw and Josh Pihl},
  title     = {{Development of models for NH$_3$ SCR storage and the impacts of hydrothermal aging}},
  booktitle = {{Proceedings of the 2020 Cross-cut Lean Exhaust Emissions Reduction Simulations (CLEERS) Virtual Workshop}},
  month     = sep # {~14--18,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/yxv95sr4}}
}

% BISON
% https://www.osti.gov/biblio/1670430-fy20-bison-bwr-fuel-modeling-capability-material-models
% https://inldigitallibrary.inl.gov/sites/sti/sti/Sort_26794.pdf
@TechReport{Toptan_2020b,
  author      = {Aysenur Toptan and Kyle Gamble},
  title       = {{FY20 BISON BWR fuel modeling capability: Material models}},
  institution = {Idaho National Laboratory},
  day         = 30,
  month       = sep,
  year        = 2020,
  number      = {INL/EXT-20-59936},
  note        = {\url{https://doi.org/10.2172/1670430}}
}

% MOOSE
% "The discretized equations developed in Section 3 have been implemented ... in ... (MOOSE)"
@Article{Ghanbari_2020,
  author  = {F. Ghanbari and F. Costanzo and D. Hughes and C. Peco},
  title   = {Phase-field modeling of constrained interactive fungal networks},
  journal = {Journal of the Mechanics and Physics of Solids},
  month   = dec,
  year    = 2020,
  volume  = 145,
  pages   = {104160 (21 pages)},
  note    = {\url{https://doi.org/10.1016/j.jmps.2020.104160}}
}

% libMesh/MOOSE/Moonolith
@Article{vonPlanta_2020,
  author  = {Cyrill von Planta and Daniel Vogler and Xiaoqing Chen and Maria G. C. Nestola and Martin O. Saar and Rolf Krause},
  title   = {{Modelling of hydro-mechanical processes in heterogeneous fracture intersections using a fictitious domain method with variational transfer operators}},
  journal = {Computational Geosciences},
  month   = oct,
  year    = 2020,
  volume  = 24,
  number  = 5,
  pages   = {1799--1814},
  note    = {\url{https://doi.org/10.1007/s10596-020-09936-7}, ArXiv e-print: \url{https://arxiv.org/abs/2001.02030}}
}

% MOOSE/INS
% "This paper demonstrates an Incompressible Navier-Stokes (INS) module in ... (MOOSE)"
@Article{Guo_2020,
  author  = {Juanjuan Guo and Shuoting Zhang and Changjiang Yang and Jun Wang and Shanfang Huang and Kan Wang},
  title   = {{Preliminary verification of incompressible Navier--Stokes equations solved by the Newton method}},
  journal = {International Journal of Advanced Nuclear Reactor Design and Technology},
  month   = oct,
  year    = 2020,
  volume  = 2,
  pages   = {69--85},
  note    = {\url{https://doi.org/10.1016/j.jandt.2020.08.001}}
}

% Moltres + MOOSE/INS
% "This work uses MOOSE's Navier-Stokes module for simulating incompressible salt flow in the MSFR."
@mastersthesis{Park_thesis,
  author = {Sun Myung Park},
  school = {University of Illinois at Urbana-Champaign},
  title  = {{Advancement and verification of Moltres for molten salt reactor safety analysis}},
  note   = {\url{http://hdl.handle.net/2142/108542}},
  month  = jun,
  year   = 2020
}

% MOOSE/INS
% "To solve the analogous creep problem using fluid mechanics, we use the Navier-Stokes module... inside MOOSE"
% https://www.osti.gov/biblio/1658590-initial-development-high-temperature-life-prediction-method-directly-accounting-variability-material-properties
@TechReport{Nicolas_2020,
  author      = {Andrea Nicolas and Mark C. Messner and T.-L. Sham},
  title       = {Initial development of a high temperature life prediction method directly accounting for variability in material properties},
  institution = {Argonne National Laboratory},
  day         = 1,
  month       = sep,
  year        = 2020,
  number      = {ANL-ART-203},
  note        = {\url{https://doi.org/10.2172/1658590}}
}

% MOOSE/SAM
@Article{Hollrah_2020,
  author  = {B. Hollrah and M. Bucknor and D. Lisowski and Y. Hassan and R. Vaghetto and R. Hu},
  title   = {{Benchmark simulation of the Natural Convection Shutdown Heat Removal Test Facility using SAM}},
  journal = {Nuclear Technology},
  month   = oct,
  year    = 2020,
  volume  = 206,
  number  = 9,
  pages   = {1337--1350},
  note    = {Special Issue: Selected papers from NURETH-18, \url{https://doi.org/10.1080/00295450.2020.1745039}}
}

% MOOSE
% "We use the finite element based ... MOOSE for implementing the proposed periodic RVE scheme."
@Article{Biswas_2020,
  author  = {Sudipta Biswas and Daniel Schwen and Jason D. Hales},
  title   = {Development of a finite element based strain periodicity implementation method},
  journal = {Finite Elements in Analysis and Design},
  month   = oct,
  year    = 2020,
  volume  = 179,
  pages   = {103436 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.finel.2020.103436}}
}

% MOOSE/phase_field
% This paper doesn't use MOOSE per se, but it is specifically about open source software for
% phase-field simulations, and MOOSE's phase_field module features prominently throughout.
@Article{ZHong_2020,
  author  = {Zijian Hong and Venkatasubramanian Viswanathan},
  title   = {Open-sourcing phase-field simulations for accelerating energy materials design and optimization},
  journal = {ACS Energy Letters},
  month   = sep,
  year    = 2020,
  volume  = 5,
  pages   = {3254--3259},
  note    = {\url{https://doi.org/10.1021/acsenergylett.0c01904}}
}

% libMesh
% libMesh is one of the software packages supported by DfAnalyzer and is used to generate Table 1 in the paper
@Article{Silva_2020,
  author  = {V{\'{i}}tor Silva and Vin{\'{i}}cius Campos and Thaylon Guedes and Jos{\'{e}} Camata and Daniel {de Oliveira} and Alvaro L. G. A. Coutinho and Patrick Valduriez and Marta Mattoso},
  title   = {{DfAnalyzer: Runtime dataflow analysis tool for computational science and engineering applications}},
  journal = {SoftwareX},
  month   = jul # {--} # dec,
  year    = 2020,
  volume  = 12,
  pages   = {100592 (6 pages)},
  note    = {\url{https://doi.org/10.1016/j.softx.2020.100592}}
}

% libMesh
% "The numerical experiments in Sections 3.5.2 to 3.5.4 have been performed using the C++ library libMesh"
% https://infoscience.epfl.ch/record/279785
@phdthesis{deSouza_thesis,
  author = {Giacomo Rosilho de Souza},
  school = {{\'{E}}cole Polytechnique F{\'{e}}d{\'{e}}rale de Lausanne (EPFL)},
  title  = {Numerical methods for deterministic and stochastic differential equations with multiple scales and high contrasts},
  note   = {\url{https://doi.org/10.5075/epfl-thesis-7445}},
  month  = sep,
  year   = 2020
}

% MOOSE
% "... the MOOSE framework was used to simulate the GeoTES with geological properties from the Weber/Tensleep formation."
@InProceedings{Jin_2020,
  author    = {W. Jin and R. Podgorney and T. McLing},
  title     = {{THM coupled numerical analysis on the geothermal energy storage \& extraction in porous fractured reservoir}},
  booktitle = {{Proceedings of the 54th U.S. Rock Mechanics/Geomechanics Symposium}},
  address   = {Golden, Colorado, USA},
  pages     = {ARMA-2020-1338 (10 pages)},
  month     = jun # {~28--} # jul # {~1,},
  year      = 2020,
  note      = {Conference cancelled, \url{https://www.onepetro.org/conference-paper/ARMA-2020-1338}}
}

% MOOSE/BISON
% "The finite-element code BISON ... were used to perform sensitivity analyses"
@Article{Gorton_2020,
  author  = {Jacob P. Gorton and Daniel Schappel and Andrew T. Nelson and Nicholas R. Brown},
  title   = {{Impact of uranium oxide (UO$_2$) fuel with molybdenum (Mo) inserts on pressurized water reactor performance and safety}},
  journal = {Journal of Nuclear Materials},
  month   = dec,
  year    = 2020,
  volume  = 542,
  pages   = {152492 (16 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152492}}
}

% MOOSE
@Article{Martineau_2020,
  author  = {R. Martineau and D. Andr{\v{s}} and R. Carlsen and D. Gaston and J. Hansel and F. Kong and A. Lindsay and C. Permann and A. Slaughter and E. Merzari and Rui Hu and A. Novak and R. Slaybaugh},
  title   = {Multiphysics for nuclear energy applications using a cohesive computational framework},
  journal = {Nuclear Engineering and Design},
  month   = oct,
  year    = 2020,
  volume  = 367,
  pages   = {110751 (9 pages)},
  note    = {\url{https://doi.org/10.1016/j.nucengdes.2020.110751}}
}

% IBAMR/libMesh
% https://search.proquest.com/openview/9de70dfceaa27a03de4e55f7bd1d94b0/1?pq-origsite=gscholar&cbl=18750&diss=y
@phdthesis{Fang_thesis,
  author = {Fuhui Fang},
  school = {University of North Carolina at Chapel Hill},
  title  = {Numerical advances for fluid-structure interaction in entangled polymer solutions with applications to active microbead rheology},
  note   = {\url{https://tinyurl.com/y6hwey55}},
  month  = aug,
  year   = 2020
}

% MOOSE/REDBACK
% "A finite element solver REDBACK ... based on the MOOSE ... framework is used to solve the above coupled equations."
% Published online July 6, 2018.
@Article{MHu_2018b,
  author  = {Manman Hu and Manolis Veveakis and Klaus {Regenauer-Lieb}},
  title   = {Influence of stress field anisotropy on drilling-induced tensile fracture},
  journal = {Environmental Geotechnics},
  month   = aug,
  year    = 2020,
  volume  = 7,
  number  = 5,
  pages   = {373--379},
  note    = {\url{https://doi.org/10.1680/jenge.17.00064}}
}

% MOOSE/REDBACK
% "All results presented in this study were obtained with the open-source REDBACK simulator ..."
% https://www.researchgate.net/publication/343889910_Permeability_hysteresis_from_micro-channels_opening_during_dissolutionreprecipitation_cycle
@Article{Lesueur_2020d,
  author  = {Martin Lesueur and Thomas Poulet and Emmanouil Veveakis},
  title   = {Permeability hysteresis from micro-channels opening during dissolution/reprecipitation cycle},
  journal = {Geophysical Research Letters},
  month   = sep,
  year    = 2020,
  volume  = 47,
  number  = 18,
  pages   = {e2020GL088674 (12 pages)},
  note    = {\url{https://doi.org/10.1029/2020GL088674}, EarthArXiv e-print: \url{https://doi.org/10.31223/osf.io/4jfv6}}
}

% MOOSE/GRIFFIN
% https://www.osti.gov/biblio/1648116-assessment-griffin-reactor-multiphysics-application-using-empire-micro-reactor-design-concept
@TechReport{CLee_2020,
  author      = {Changho Lee and Yeon Sang Jung and Zhaopeng Zhong and Javier Ortensi and Vicent Labour{\'{e}} and Yaqi Wang and Mark DeHart},
  title       = {{Assessment of the Griffin reactor multiphysics application using the Empire micro reactor design concept}},
  institution = {Argonne National Laboratory},
  day         = 31,
  month       = jul,
  year        = 2020,
  number      = {ANL/NSE-20/23},
  note        = {\url{https://doi.org/10.2172/1648116}}
}

% MOOSE
% "Codes developed by DOE such as MOOSE, BISON, PRONGHORN, SAM, and MAMMOTH are expected to be utilized extensively."
% https://www.semanticscholar.org/paper/The-U.S.-Nuclear-Regulatory-Commission-Approach-to-Bajorek/5ce1ead1c5312c45efeb97ab6f4a0920e3126cdd
@Misc{Bajorek_2020,
  author       = {Stephen M. Bajorek},
  title        = {{The U.S. Nuclear Regulatory Commission approach to modeling and simulation of advanced non-LWRs}},
  month        = aug,
  year         = 2020,
  howpublished = {Report},
  note         = {\url{https://tinyurl.com/yywusucb}}
}

% MOOSE/phase_field
% "The non-dimensionalized governing equations were discretized using the MOOSE framework ..."
@Article{Aagesen_2020,
  author  = {Larry K. Aagesen and David Andersson and Benjamin W. Beeler and Michael W. D. Cooper and Kyle A. Gamble and Yinbin Miao and Giovanni Pastore and Michael R. Tonks},
  title   = {{Phase-field simulations of intergranular fission gas bubble behavior in U$_3$Si$_2$ nuclear fuel}},
  journal = {Journal of Nuclear Materials},
  month   = dec,
  year    = 2020,
  volume  = 541,
  pages   = {152415 (38 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152415}}
}

% MOOSE/phase_field
% "To create the simulated structures and evaluate their effective thermal conductivity,
% the (MOOSE) finite element framework ... was utilized."
@Article{Hilty_2020,
  author  = {Floyd W. Hilty and Michael R. Tonks},
  title   = {{Development and application of a microstructure dependent thermal resistor model for UO$_2$ reactor fuel with high thermal conductivity additives}},
  journal = {Journal of Nuclear Materials},
  month   = nov,
  year    = 2020,
  volume  = 540,
  pages   = {152334 (19 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152334}}
}

% MOOSE/phase_field
% "The phase-field equations are solved using the open-source MOOSE framework."
@Article{Hong_2020,
  author  = {Zijian Hong and Zeeshan Ahmad and Venkatasubramanian Viswanathan},
  title   = {{Design principles for dendrite suppression with porous polymer/aqueous solution hybrid electrolyte for Zn metal anodes}},
  journal = {ACS Energy Letters},
  month   = jun,
  year    = 2020,
  volume  = 5,
  number  = 8,
  pages   = {2466--2474},
  note    = {\url{https://doi.org/10.1021/acsenergylett.0c01235}}
}

% MOOSE
% "We perform numerical simulations using a finite-element method-based numerical simulator (MOOSE framework) ..."
@Article{Lima_2020,
  author  = {Marina Grimm Lima and Philipp Sch{\"{a}}dle and Christopher P. Green and Daniel Vogler and Martin O. Saar and Xiang-Zhao Kong},
  title   = {{Permeability impairment and salt precipitation patterns during CO$_2$ injection into single natural brine-filled fractures}},
  journal = {Water Resources Research},
  month   = aug,
  year    = 2020,
  volume  = 56,
  number  = 8,
  pages   = {e2020WR027213 (30 pages)},
  note    = {\url{https://doi.org/10.1029/2020WR027213}}
}

% MOOSE/phase_field
% "Self-consistent solutions to this equation are obtained by using the (MOOSE) finite-element platform"
@Article{Koushan_2020,
  author  = {Foroozan S. Koushan and Nobuhiko P. Kobayashi},
  title   = {{An electro-thermal computational study of conducting channels in dielectric thin films using self-consistent phase-field methodology: A view toward the physical origins of resistive switching}},
  journal = {Journal of Applied Physics},
  month   = oct,
  year    = 2020,
  volume  = 128,
  number  = 16,
  pages   = {165302 (7 pages)},
  note    = {\url{https://doi.org/10.1063/5.0027702}, ArXiv e-print: \url{https://arxiv.org/abs/2007.15123}}
}

% libMesh
% "The discrete equations are solved using distributed data structures provided by libMesh ..."
@Article{Mesgarnejad_2020b,
  author  = {A. Mesgarnejad and C. Pan and R. M. Erb and S. J. Shefelbine and A. Karma},
  title   = {Crack path selection in orientationally ordered composites},
  journal = {Physical Review E},
  month   = jul,
  year    = 2020,
  volume  = 102,
  pages   = {013004 (17 pages)},
  note    = {\url{https://doi.org/10.1103/PhysRevE.102.013004}, ArXiv e-print: \url{https://arxiv.org/abs/1811.05891}}
}

% MOOSE/phase_field
% "The non-dimensional evolution equations are discretized and
% solved using the finite element method, as implemented in the
% MOOSE framework"
@Article{Kadambi_2020,
  author  = {Sourabh B. Kadambi and Fadi Abdeljawad and Srikanth Patala},
  title   = {{Interphase boundary segregation and precipitate coarsening resistance in ternary alloys: An analytic phase-field model describing chemical effects}},
  journal = {Acta Materialia},
  month   = sep,
  year    = 2020,
  volume  = 197,
  pages   = {283--299},
  note    = {\url{https://doi.org/10.1016/j.actamat.2020.06.052}}
}

% MOOSE/phase_field
% "... a generic free energy formulation was adopted in our modeling and simulations, and was solved efficiently within MOOSE"
@Article{Sun_2020,
  author  = {Cheng Sun and Yipeng Gao and David J. Sprouster and Yongfeng Zhang and Di Chen and Yongqiang Wang and Lynne E. Ecker and Jian Gan},
  title   = {Disordering of helium gas bubble superlattices in molybdenum under ion irradiation and thermal annealing},
  journal = {Journal of Nuclear Materials},
  month   = oct,
  year    = 2020,
  volume  = 539,
  pages   = {152315 (7 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152315}}
}

% MOOSE
% "These constitutive equations are implemented as a material
% model and interfaced with the open source code ... (MOOSE)"
@Article{Thool_2020,
  author  = {Khushahal Thool and Anirban Patra and David Fullwood and K. V. Mani Krishna and Dinesh Srivastava and Indradev Samajdar},
  title   = {{The role of crystallographic orientations on heterogeneous deformation in a zirconium alloy: A combined experimental and modeling study}},
  journal = {International Journal of Plasticity},
  month   = oct,
  year    = 2020,
  volume  = 133,
  pages   = {102785 (55 pages)},
  note    = {\url{https://doi.org/10.1016/j.ijplas.2020.102785}}
}

% MOOSE
% https://www.researchgate.net/publication/328800602_Solution_of_contact_problems_between_rough_body_surfaces_with_non_matching_meshes_using_a_parallel_mortar_method
@Article{vonPlanta_2020b,
  author  = {Cyrill von Planta and Daniel Vogler and Patrick Zulian and Martin O. Saar and Rolf Krause},
  title   = {Contact between rough rock surfaces using a dual mortar method},
  journal = {International Journal of Rock Mechanics and Mining Sciences},
  month   = sep,
  year    = 2020,
  volume  = 133,
  pages   = {104414 (10 pages)},
  note    = {\url{https://doi.org/10.1016/j.ijrmms.2020.104414}, ArXiv e-print: \url{https://arxiv.org/abs/1811.02914}}
}

% MOOSE
% "Here, we adopt the Multiphysics Object-Oriented Simulation Environment..."
% https://www.researchgate.net/profile/Elyas_Goli/publication/342296362_Impact_of_Boundary_Heat_Losses_on_Frontal_Polymerization/links/5eefb8ed299bf1faac6c88d0/Impact-of-Boundary-Heat-Losses-on-Frontal-Polymerization.pdf
@Article{Goli_2020c,
  author  = {Elyas Goli and Tianyu Gai and Philippe H. Geubelle},
  title   = {Impact of boundary heat losses on frontal polymerization},
  journal = {The Journal of Physical Chemistry B},
  month   = jul,
  year    = 2020,
  volume  = 124,
  number  = 29,
  pages   = {6404--6411},
  note    = {\url{https://doi.org/10.1021/acs.jpcb.0c03107}}
}

% MOOSE/phase_field
% "... we utilize the phase-field model of grain growth that is implemented
% in the open-source MOOSE framework"
% A new model for the effective thermal conductivity of polycrystalline solids
@Article{Badry_2020,
  author  = {Fergany Badry and Karim Ahmed},
  title   = {{A new model for the effective thermal conductivity of polycrystalline solids}},
  journal = {AIP Advances},
  month   = oct,
  year    = 2020,
  volume  = 10,
  number  = 10,
  pages   = {105021 (17 pages)},
  note    = {\url{https://doi.org/10.1063/5.0022375}, ArXiv e-print: \url{https://arxiv.org/abs/2007.10423}}
}

% libMesh
% "In order to reduce the computational cost of the phase field
% method, the problem is solved over an h-adaptive mesh, using
% libMesh..."
@Article{Sadasiva_2020,
  author  = {S. Sadasiva and P. Vaitheeswaran and G. Subbarayan},
  title   = {A phase field computational procedure for electromigration with specified contact angle and diffusional anisotropy},
  journal = {Computational Mechanics},
  month   = aug,
  year    = 2020,
  volume  = 66,
  number  = 2,
  pages   = {373--390},
  note    = {\url{https://doi.org/10.1007/s00466-020-01855-9}}
}

% "In this work ... Cahn-Hilliard equation was solved using finite element method (FEM) in ... (MOOSE) Framework software"
@Article{Hussain_2020,
  author  = {Muhammad Muzammal Hussain and Haitao Ma and Mingliang Huang and Zhaoqing Gao and Jinwei Cao and Chen Wang and Chong Dong and Yunpeng Wang and Anil Kunwar},
  title   = {{Fabrication of cerium myristate coating for a mechanochemically robust modifier-free superwettability system to enhance the corrosion resistance on 316L steel by one-step electrodeposition}},
  journal = {Surface and Coatings Technology},
  month   = sep,
  year    = 2020,
  volume  = 398,
  pages   = {125970 (39 pages)},
  note    = {\url{https://doi.org/10.1016/j.surfcoat.2020.125970}}
}

% MOOSE/MAMMOTH/PRONGHORN
% https://www.researchgate.net/publication/342903342_PBMR-400_BENCHMARK_SOLUTION_OF_EXERCISE_1_AND_2_USING_THE_MOOSE_BASED_APPLICATIONS_MAMMOTH_PRONGHORN
@InProceedings{Balestra_2020,
  author    = {Paolo Balestra and Sebastian Schunert and Robert W. Carlsen and April J. Novak and Mark D. Dehart and Richard C. Martineau},
  title     = {{PBMR-400 benchmark solution of exercise 1 and 2 using the MOOSE based applications: MAMMOTH, PRONGHORN}},
  booktitle = {{Proceedings of the International Conference on Physics of Reactors (PHYSOR 2020)}},
  address   = {Cambridge, United Kingdom},
  publisher = {American Nuclear Society},
  month     = mar # {~29--} # apr # {~2,},
  year      = 2020,
  pages     = {06020 (13 pages)},
  note      = {Conference cancelled, Papers published in EPJ Web of Conferences v.~247, \url{https://doi.org/10.1051/epjconf/202124706020}}
}

% MOOSE/SAM
@InProceedings{Fei_2020,
  author    = {T. Fei and T. Hua and B. Feng and F. Heidet and R. Hu},
  title     = {{MSRE transient benchmarks using SAM}},
  booktitle = {{Proceedings of the International Conference on Physics of Reactors (PHYSOR 2020)}},
  address   = {Cambridge, United Kingdom},
  publisher = {American Nuclear Society},
  month     = mar # {~29--} # apr # {~2,},
  year      = 2020,
  pages     = {07008 (8 pages)},
  note      = {Conference cancelled, Papers published in EPJ Web of Conferences v.~247, \url{https://doi.org/10.1051/epjconf/202124707008}}
}

% MOOSE
% "... the set of Eqs. (15), (18) and (22) were solved using ... (FEM) in ... (MOOSE)"
@Article{Kunwar_2020b,
  author  = {Anil Kunwar and Yuri Amorim Coutinho and Johan Hektor and Haitao Ma and Nele Moelans},
  title   = {{Integration of machine learning with phase field method to model the electromigration induced anode Cu$_6$Sn$_5$ IMC growth at Cu-Sn interface}},
  journal = {Journal of Materials Science \& Technology},
  month   = dec,
  year    = 2020,
  volume  = 59,
  pages   = {203--219},
  note    = {\url{https://doi.org/10.1016/j.jmst.2020.04.046}}
}

% MOOSE/BISON
% "The work presented here uses the BISON fuel performance code ..."
@Article{Capps_2020,
  author  = {Nathan Capps and Ryan Sweet and Brian D. Wirth and Andrew Nelson and Kurt Terrani},
  title   = {{Development and demonstration of a methodology to evaluate high burnup fuel susceptibility to pulverization under a loss of coolant transient}},
  journal = {Nuclear Engineering and Design},
  month   = sep,
  year    = 2020,
  volume  = 366,
  pages   = {110744 (17 pages)},
  note    = {\url{https://doi.org/10.1016/j.nucengdes.2020.110744}}
}

% MOOSE/BISON
% "The BISON fuel performance code was used to perform a comparative analysis ..."
@Article{Sweet_2020,
  author  = {R. T. Sweet and Y. Yang and K. A. Terrani and B. D. Wirth and A. T. Nelson},
  title   = {{Performance of U$_3$Si$_2$ in an LWR following a cladding breach during normal operation}},
  journal = {Journal of Nuclear Materials},
  month   = oct,
  year    = 2020,
  volume  = 539,
  pages   = {152263 (33 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152263}}
}

% MAST - Multidisciplinary-design Adaptation and Sensitivity Toolkit
% Uses libMesh internally.
@InProceedings{Arsalane_2020,
  author    = {Walid Arsalane and Manav Bhatia},
  title     = {Structural sizing of post-buckled thermally stressed stiffened panel},
  booktitle = {{Proceedings of the AIAA Aviation 2020 Forum}},
  address   = {Virtual Event},
  month     = jun # {~15--19,},
  year      = 2020,
  pages     = {AIAA 2020-3180 (21 pages)},
  note      = {\url{https://doi.org/10.2514/6.2020-3180}}
}

% MOOSE
% "All simulations in this study were performed using the MOOSE ... framework"
@Article{Vogler_2020,
  author  = {Daniel Vogler and Stuart D. C. Walsh and Philipp Rudolf von Rohr and Martin O. Saar},
  title   = {Simulation of rock failure modes in thermal spallation drilling},
  journal = {Acta Geotechnica},
  month   = aug,
  year    = 2020,
  volume  = 15,
  number  = 8,
  pages   = {2327--2340},
  note    = {\url{https://doi.org/10.1007/s11440-020-00927-7}}
}

% MOOSE/phase_field
% "The grain growth model has been implemented in the MOOSE/MARMOT framework ..."
% https://www.osti.gov/biblio/1634828-modeling-time-dependent-surrogates-additive-manufactured-nuclear-fuels-processes
% https://www.osti.gov/servlets/purl/1634828
@TechReport{CWang_2020,
  author      = {Congjian Wang and Wen Jiang and Yipeng Gao},
  title       = {{Modeling time-dependent surrogates of additive-manufactured nuclear fuels processes}},
  institution = {Idaho National Laboratory},
  day         = 11,
  month       = jun,
  year        = 2020,
  number      = {INL/CON-20-57376},
  note        = {\url{https://tinyurl.com/y8kmj9a8}}
}

% MOOSE/BISON
% "The transport model has been implemented within the nuclear fuel performance code BISON"
@Article{Simunovic_2020,
  author  = {Srdjan Simunovic and Theodore M. Besmann and Emily Moore and Max Poschmann and Markus H. A. Piro and Kevin T. Clarno and Jake W. McMurray and William A. Wieselquist},
  title   = {{Modeling and simulation of oxygen transport in high burnup LWR fuel}},
  journal = {Journal of Nuclear Materials},
  month   = sep,
  year    = 2020,
  volume  = 538,
  pages   = {152194 (10 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152194}}
}

% MOOSE/RACCOON
% "RACCOON is built upon the MOOSE framework [65] developed at the Idaho National Laboratory..."
% https://doi.org/10.13140/RG.2.2.15131.41767
@Article{Hu_2020,
  author  = {Tianchen Hu and Johann Guilleminot and John E. Dolbow},
  title   = {{A phase-field model of fracture with frictionless contact and random fracture properties: Application to thin-film fracture and soil desiccation}},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = aug,
  year    = 2020,
  volume  = 368,
  pages   = {113106 (39 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2020.113106}}
}

% MOOSE/BISON
% "The model is being implemented into Idaho National Laboratory's fuel performance code BISON..."
@Article{Barani_2020,
  author  = {T. Barani and G. Pastore and A. Magni and D. Pizzocri and P. {Van Uffelen} and L. Luzzi},
  title   = {Modeling intra-granular fission gas bubble evolution and coarsening in uranium dioxide during in-pile transients},
  journal = {Journal of Nuclear Materials},
  month   = sep,
  year    = 2020,
  volume  = 538,
  pages   = {152195 (42 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152195}}
}

% MOOSE
% "In this paper, the finite element mechanics analysis software MOOSE ...
% is adopted to analyze the COD deformation introduced by pressure."
@Article{JZhang_2020,
  author  = {Jing Zhang and Chenxi Li and Jian Deng and Hao Sun and Yingwei Wu and Mingjun Wang and Dalin Zhang and Wenxi Tian and Suizheng Qiu and Guanghui Su},
  title   = {Experimental and theoretical study on fluid-structure interaction and non-equilibrium of the flow through micro cracks},
  journal = {Annals of Nuclear Energy},
  month   = jul,
  year    = 2020,
  volume  = 142,
  pages   = {107441 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2020.107441}}
}

% libMesh
% "Utopia wraps functions from LibMesh ... for the finite element assembly."
% https://doc.rero.ch/record/328473/files/2020INFO005.pdf
@phdthesis{Bendusi_thesis,
  author = {Pietro Bendusi},
  school = {Universit{\`{a}} della Svizzera Italiana},
  title  = {Parallel space-time multilevel methods with application to electrophysiology: Theory and implementation},
  note   = {\url{https://doc.rero.ch/record/328473}},
  month  = may,
  year   = 2020
}

% libMesh
% "This model is implemented using the libMesh finite element library ..."
@Article{Mercenier_2020,
  author  = {R. Mercenier and M. P. L{\"{u}}thi and A. Vieli},
  title   = {How oceanic melt controls tidewater glacier evolution},
  journal = {Geophysical Research Letters},
  month   = apr,
  year    = 2020,
  volume  = 47,
  number  = 8,
  pages   = {e2019GL086769 (9 pages)},
  note    = {\url{https://doi.org/10.1029/2019GL086769}}
}

% MOOSE
% "These explicit pebble coupling approaches leverage the MultiApp features available in the MOOSE framework."
@TechReport{Ortensi_2020,
  author      = {Paolo Balestra and Zachary M. Prince and Javier Ortensi and Sebastian Schunert and Yaqi Wang and William M. Hoffman and Albert Casagranda and Mark D. DeHart},
  title       = {{NRC Multiphysics Analysis Capability Deployment FY2020 -- Part 3}},
  institution = {Idaho National Laboratory},
  day         = 8,
  month       = jun,
  year        = 2020,
  number      = {INL/EXT-20-58485},
  note        = {\url{https://doi.org/10.2172/1632281}}
}

% MOOSE
% "... (PJFNK) method is implemented in ... (MOOSE) Framework ... to perform the finite element analysis."
@Article{Kunwar_2020,
  author  = {Anil Kunwar and Johan Hektor and Sukeharu Nomoto and Yuri Amorim Coutinho and Nele Moelans},
  title   = {{Combining multi-phase field simulation with neural network analysis to unravel thermomigration accelerated growth of Cu$_6$Sn$_5$ IMC at cold side Cu-Sn interface}},
  journal = {International Journal of Mechanical Sciences},
  month   = oct,
  year    = 2020,
  volume  = 184,
  pages   = {105843 (20 pages)},
  note    = {\url{https://doi.org/10.1016/j.ijmecsci.2020.105843}}
}

% MOOSE
% "The model is implemented in INL's MOOSE software ..."
% https://digital.lib.washington.edu/researchworks/bitstream/handle/1773/45524/Ferguson_washington_0250E_20866.pdf?sequence=1
@phdthesis{Ferguson_thesis,
  author = {Bryan Ferguson},
  school = {University of Washington},
  title  = {Modeling and experimental analysis of superplastic forming and diffusion bonding},
  note   = {\url{http://hdl.handle.net/1773/45524}},
  month  = may,
  year   = 2020
}

% "For the finite element discretization we use libMesh..."
@Article{Rittich_2020,
  author  = {Hannah Rittich and Robert Speck},
  title   = {{Time-parallel simulation of the Schr{\"{o}}dinger equation}},
  journal = {Computer Physics Communications},
  month   = oct,
  year    = 2020,
  volume  = 255,
  pages   = {107363 (13 pages)},
  note    = {\url{https://doi.org/10.1016/j.cpc.2020.107363}, ArXiv e-print: \url{https://arxiv.org/abs/1912.03312}}
}

% MOOSE
% "All numerical tests have been implemented in the FE framework MOOSE."
@Article{Favino_2020,
  author  = {Marco Favino and J{\"{u}}rg Hunziker and Eva Caspari and Beatriz Quintal and Klaus Holliger and Rolf Krause},
  title   = {{Fully-automated adaptive mesh refinement for media embedding complex heterogeneities: Application to poroelastic fluid pressure diffusion}},
  journal = {Computational Geosciences},
  month   = apr,
  year    = 2020,
  volume  = 24,
  pages   = {1101--1120},
  note    = {\url{https://doi.org/10.1007/s10596-019-09928-2}}
}

% libMesh
% "The numerical experiments in Sections 5.2 to 5.4 were performed using the C++ library libMesh"
% MATHICSE Tech. Report \url{https://infoscience.epfl.ch/record/277896}
% https://www.researchgate.net/publication/341817042_Stabilized_explicit_multirate_methods_for_stiff_differential_equations
% author:abdulle author:grote Stabilized explicit multirate methods for stiff differential equations
@Misc{Abdulle_2020b,
  author       = {Assyr Abdulle and Marcus J. Grote and Giacomo Rosilho de Souza},
  title        = {Stabilized explicit multirate methods for stiff differential equations},
  month        = jun,
  year         = 2020,
  howpublished = {ArXiv e-print and MATHICSE Tech. Report 277896},
  note         = {\url{https://arxiv.org/abs/2006.00744}, \url{https://doi.org/10.5075/epfl-MATHICSE-277896}}
}

% libMesh
% "The last experiment has been performed with the help of the C++ library libMesh"
% Note: very similar title to Abdulle_2020b, but this is a different paper.
% MATHICSE Tech. Report \url{https://infoscience.epfl.ch/record/281675}
% https://www.researchgate.net/publication/344972164_Explicit_stabilized_multirate_method_for_stiff_stochastic_differential_equations
% author:abdulle author:de-souza stochastic differential equations
@Misc{Abdulle_2020c,
  author       = {Assyr Abdulle and Giacomo Rosilho de Souza},
  title        = {Explicit stabilized multirate method for stiff stochastic differential equations},
  month        = oct,
  year         = 2020,
  howpublished = {ArXiv e-print},
  note         = {\url{https://arxiv.org/abs/2010.15193}}
}

% MOOSE
% https://search.proquest.com/openview/4bc7e0c9c5a2cda5d75722ddb09b8b39/1?pq-origsite=gscholar&cbl=18750&diss=y
@phdthesis{Saklani_2020b,
  author = {Naman Saklani},
  school = {Arizona State University},
  title  = {{Implementation of a coupled creep damage model in MOOSE finite element framework: Application to irradiated concrete structures}},
  note   = {\url{https://tinyurl.com/y8lwweto}},
  month  = may,
  year   = 2020
}

% MOOSE
% "Based on available modeling and simulation capabilities of
% peridynamics module in MOOSE framework for oxide fuel ..."
% https://permalink.lanl.gov/object/tr?what=info:lanl-repo/lareport/LA-UR-20-23767
% https://www.osti.gov/biblio/1630837-modeling-metallic-fuel-using-peridynamics
@TechReport{Chen_2020,
  author      = {Hailong Chen and Cetin Unal},
  title       = {Modeling metallic fuel using peridynamics},
  institution = {Nuclear Energy University Programs (NEUP)},
  day         = 20,
  month       = may,
  year        = 2020,
  number      = {LA-UR-20-23767},
  note        = {\url{https://doi.org/10.2172/1630837}}
}

% MOOSE
% MOOSE is one of the codes they test their floating point analysis software on
% http://pdinda.org/Papers/hpdc20.pdf
@InProceedings{Dinda_2020,
  author    = {Peter Dinda and Alex Bernat and Conor Hetland},
  title     = {{Spying on the floating point behavior of existing, unmodified scientific applications}},
  booktitle = {{Proceedings of the 29th International Symposium on High-Performance Parallel and Distributed Computing (HPDC'20)}},
  address   = {Stockholm, Sweden},
  pages     = {5--16},
  month     = jun # {~23--26,},
  year      = 2020,
  note      = {\url{https://doi.org/10.1145/3369583.3392673}}
}

% MOOSE
% "All simulations have been performed using ... MOOSE"
@Article{Simon_2020,
  author  = {Pierre-Cl{\'{e}}ment A. Simon and Larry K. Aagesen and Arthur T. Motta and Michael R. Tonks},
  title   = {The effects of introducing elasticity using different interpolation schemes to the grand potential phase field model},
  journal = {Computational Materials Science},
  month   = oct,
  year    = 2020,
  volume  = 183,
  pages   = {109790 (10 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2020.109790}}
}

% MOOSE
% "This approach is implemented in the Ferret application,
% built upon the ... (MOOSE) finite-element framework"
@Article{Kuna_2020,
  author  = {Lukasz Kuna and John Mangeri and Edward P. Gorzkowski and James A. Wollmershauser and Serge Nakhmanson},
  title   = {Mesoscale modeling of light transmission modulation in ceramics},
  journal = {Acta Materialia},
  month   = jul,
  year    = 2020,
  volume  = 193,
  pages   = {261--269},
  note    = {\url{https://doi.org/10.1016/j.actamat.2020.03.040}}
}

% libMesh
% "The resulting discrete forms are implemented in C++ using the open source libMesh library"
% http://periodicos.ifpr.edu.br/index.php?journal=MundiETG&page=article&op=view&path%5B%5D=1142&path%5B%5D=488
% Appears to be a special issue of this journal with conference papers from XXII Encontro Nacional de Modelagem Computacional
@Article{Resende_2020,
  author  = {Anna Claudia Mello de Resende and Rafael Alves Bonfim de Queiroz and Ernesto Augusto Bueno da Fonseca Lima and Gustavo Taiji Naozuka and Regina C{\'{e}}lia Cerqueira de Almeida},
  title   = {An imaging-driven, mechanical deformation-coupled reaction-diffusion model for describing tumor development},
  journal = {Revista Mundi, Engenharia, Tecnologia e Gest{\~{a}}o},
  month   = may,
  year    = 2020,
  volume  = 5,
  number  = 2,
  pages   = {217 (13 pages)},
  note    = {\url{https://doi.org/10.21575/25254782rmetg2020vol5n21142}}
}

% libMesh
% "We implement the whole model in libMesh ..."
% There is a related conference paper/dissertation defense here:
% https://www.researchgate.net/publication/341574809_A_new_convected_level-set_method_for_gas_bubble_dynamics_Malu_Grave
@Article{Grave_2020b,
  author  = {Mal{\'{u}} Grave and Jos{\'{e}} J. Camata and Alvaro L. G. A. Coutinho},
  title   = {A new convected level-set method for gas bubble dynamics},
  journal = {Computers \& Fluids},
  month   = sep,
  year    = 2020,
  volume  = 209,
  pages   = {104667 (23 pages)},
  note    = {\url{https://doi.org/10.1016/j.compfluid.2020.104667}}
}

% MOOSE/Pronghorn
% https://www.researchgate.net/publication/341553031_Multiscale_Thermal-Hydraulic_Methods_for_Pebble_Bed_Reactors
@phdthesis{Novak_thesis,
  author = {April Novak},
  school = {University of California, Berkeley},
  title  = {{Multiscale thermal-hydraulic methods for pebble bed reactors}},
  note   = {\url{https://tinyurl.com/y7eladcj}},
  month  = may,
  year   = 2020
}

% MOOSE
% "... a three-dimensional finite element analysis (FEA) model was set up in MOOSE ..."
@Article{RJiang_2020,
  author  = {Runbo Jiang and Amir Mostafaei and Ziheng Wu and Ann Choi and Pin-Wen Guan and Markus Chmielus and Anthony D. Rollett},
  title   = {Effect of heat treatment on microstructural evolution and hardness homogeneity in laser powder bed fusion of alloy 718},
  journal = {Additive Manufacturing},
  month   = may,
  year    = 2020,
  pages   = {101282 (38 pages)},
  note    = {\url{https://doi.org/10.1016/j.addma.2020.101282}}
}

@TechReport{Eapen_2020,
  author      = {Jacob Eapen},
  title       = {{Microstructure experiments-enabled MARMOT simulations of SiC/SiC-based accident tolerant nuclear fuel system}},
  institution = {Nuclear Energy University Programs (NEUP)},
  day         = 7,
  month       = may,
  year        = 2020,
  number      = {DE-NE0008577, 16-10668},
  note        = {\url{https://doi.org/10.2172/1617561}}
}

% MOOSE/phase_field
% "The PFM is developed employing MOOSE framework"
@Article{Ramasubramanian_2020,
  author  = {Ajaykrishna Ramasubramanian and Vitaliy Yurkiv and Marco Ragone and Tara Foroozan and Reza Shahbazian-Yassar},
  title   = {{The influence of Solid Electrolyte Interface (SEI) on Li dendrites formation in Li-metal battery}},
  journal = {{ECS} Meeting Abstracts},
  month   = may,
  year    = 2020,
  volume  = {{MA}2020-01},
  number  = 2,
  pages   = {282 (1 page)},
  note    = {\url{https://doi.org/10.1149/ma2020-012282mtgabs}}
}

% MOOSE/FERRET
% "... solutions of equations ... implemented in the MOOSE-FERRET package."
% The main article does not cite MOOSE or FERRET, click on the "Supplementary
% Information" link and search for MOOSE there.
@Article{Lukyanchuk_2020,
  author  = {I. Luk'yanchuk and Y. Tikhonov and A. Razumnaya and V. M. Vinokur},
  title   = {Hopfions emerge in ferroelectrics},
  journal = {Nature Communications},
  month   = may,
  year    = 2020,
  volume  = 11,
  pages   = {2433 (7 pages)},
  note    = {\url{https://doi.org/10.1038/s41467-020-16258-w}, ArXiv e-print: \url{https://arxiv.org/abs/1907.03866}}
}

% MOOSE/BISON
% Link to book: https://www.springer.com/us/book/9783319446790
% Link to the chapter: https://doi.org/10.1007/978-3-319-50257-1_131-1
@InCollection{Spencer_2020,
  author    = {Benjamin Spencer and Daniel Schwen and Jason Hales},
  title     = {Multiphysics modeling of nuclear materials},
  pages     = {2293--2312},
  publisher = {Springer},
  year      = 2020,
  editor    = {W. Andreoni and S. Yip},
  booktitle = {Handbook of Materials Modeling, Applications: Current and Emerging Materials},
  note      = {\url{https://tinyurl.com/ycn84xdv}}
}

% libMesh
% "Our implementation is based on... libMesh [55] for finite elements bookkeeping."
% author:mesgarnejad vulnerable window of yield strength
@Article{Mesgarnejad_2020,
  author  = {Ataollah Mesgarnejad and Alain Karma},
  title   = {Vulnerable window of yield strength for swelling-driven fracture of phase-transforming battery materials},
  journal = {npj Computational Materials},
  month   = may,
  year    = 2020,
  volume  = 6,
  pages   = {58 (10 pages)},
  note    = {\url{https://doi.org/10.1038/s41524-020-0315-8}, ArXiv e-print: \url{https://arxiv.org/abs/1908.02175}}
}

% MOOSE
% "Solving the thermo-chemical PDEs ... MOOSE is adopted in this work."
% https://www.researchgate.net/publication/341342322_Instabilities_driven_by_frontal_polymerization_in_thermosetting_polymers_and_composites
@Article{Goli_2020b,
  author  = {Elyas Goli and Suzanne R. Peterson and Philippe H. Geubelle},
  title   = {Instabilities driven by frontal polymerization in thermosetting polymers and composites},
  journal = {Composites Part B: Engineering},
  month   = oct,
  year    = 2020,
  volume  = 199,
  pages   = {108306 (8 pages)},
  note    = {\url{https://doi.org/10.1016/j.compositesb.2020.108306}, ArXiv e-print: \url{https://arxiv.org/abs/2005.05929}}
}

% IBAMR/BeatIt/LibMesh
@Article{VadalaRoth_2020,
  author  = {Ben {Vadala-Roth} and Shashank Acharya and Neelesh A. Patankar and Simone Rossi and Boyce E. Griffith},
  title   = {{Stabilization approaches for the hyperelastic immersed boundary method for problems of large-deformation incompressible elasticity}},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = jun,
  year    = 2020,
  volume  = 365,
  pages   = {112978 (48 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2020.112978}, ArXiv e-print: \url{https://arxiv.org/abs/1811.06620}}
}

% MOOSE
% "It relies on the image reader capability of the finite element framework MOOSE"
% author:lesueur author:rattez permeability computation of high resolution
@Misc{Lesueur_2020b,
  author       = {Martin Lesueur and Hadrien Rattez and Oriol Colom{\'{e}}s},
  title        = {{Permeability computation of high resolution $\mu$CTscan with an unfitted boundary method to improve accuracy}},
  month        = apr,
  year         = 2020,
  howpublished = {EarthArXiv e-print},
  note         = {\url{https://doi.org/10.31223/osf.io/ernyp}}
}

% MOOSE/BISON
% "In this study, the mechanical performance of the MMLC has been
% evaluated in two ways: ... Both were carried out using the BISON
% fuel performance code."
@Article{Rezwan_2020,
  author  = {Aashique A. Rezwan and Michael R. Tonks and Michael P. Short},
  title   = {{Evaluations of the performance of multi-metallic layered composite cladding for the light water reactor accident tolerant fuel}},
  journal = {Journal of Nuclear Materials},
  month   = jul,
  year    = 2020,
  volume  = 535,
  pages   = {152136 (11 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152136}}
}

% MOOSE/MELON
% "The development of the MELON framework and equations that are
% derived from it have been implemented in the MOOSE library..."
% Note: This citation is in the "Supplementary Materials" document,
% not the main article.
@Article{Laghmach_2020,
  author  = {Rabia Laghmach and Michele {Di Pierro} and Davit A. Potoyan},
  title   = {{Mesoscale liquid model of chromatin recapitulates large-scale organization of eukaryotic cell nuclei}},
  journal = {Biophysical Journal},
  month   = may,
  year    = 2020,
  volume  = 118,
  number  = 9,
  pages   = {2130--2140},
  note    = {\url{https://doi.org/10.1016/j.bpj.2019.09.013}, bioR$\chi$iv e-print: \url{https://doi.org/10.1101/634980}}
}

% MOOSE/BISON
% https://www.osti.gov/biblio/1615992-acceleration-thermochimica-calculations-bison
% https://info.ornl.gov/sites/publications/Files/Pub137676.pdf
@TechReport{Poschmann_2020b,
  author      = {Max Poschmann and Markus H. A. Piro and Srdjan Simunovic},
  title       = {{Acceleration of Thermochimica calculations in Bison}},
  institution = {Oak Ridge National Laboratory},
  day         = 1,
  month       = jan,
  year        = 2020,
  number      = {ORNL/TM-2020/1473},
  note        = {\url{https://doi.org/10.2172/1615992}}
}

% MOOSE/BISON
% "A high fidelity, two-way coupling is presented between MPACT/CTF and Bison."
@Article{Stimpson_2020,
  author  = {S. Stimpson and K. Clarno and R. Pawlowski and R. Gardner and J. Powers and B. Collins and A. Toth and S. Novascone and S. Pitts and J. Hales and G. Pastore},
  title   = {{Coupled fuel performance calculations in VERA and demonstration on Watts Bar unit 1, cycle 1}},
  journal = {Annals of Nuclear Energy},
  month   = sep,
  year    = 2020,
  volume  = 145,
  pages   = {107554 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2020.107554}}
}

% MOOSE
% https://cmu.primo.exlibrisgroup.com/permalink/01CMU_INST/6lpsnm/alma991019697189604436
% DOI: https://doi.org/10.1184/R1/12174540.v1 (was not active when I tried it)
@phdthesis{Ogawa_thesis,
  author = {Shohei Ogawa},
  school = {Carnegie Mellon University},
  title  = {Three-dimensional image-based modeling of microscale phenomena in polymer electrolyte fuel cells},
  note   = {\url{https://tinyurl.com/ybrksw7w}},
  month  = may,
  year   = 2020
}

% MOOSE/BISON
@TechReport{Toptan_2020,
  author      = {Aysenur Toptan and Nathan W. Porter and Jason D. Hales and Richard Williamson and Martin Pilch},
  title       = {{FY20 Verification of BISON using analytic and manufactured solutions}},
  institution = {Sandia National Laboratories},
  day         = 31,
  month       = mar,
  year        = 2020,
  number      = {SAND2020-3887R, CASL-U-2020-1939-000},
  note        = {\url{https://doi.org/10.2172/1614683}}
}

% MOOSE/phase_field
@Article{Noble_2020,
  author  = {M. W. Noble and M. R. Tonks and S. P. Fitzgerald},
  title   = {{Turing instability in the solid state: Void lattices in irradiated metals}},
  journal = {Physical Review Letters},
  month   = apr,
  year    = 2020,
  volume  = 124,
  number  = 16,
  pages   = {167401 (6 pages)},
  note    = {\url{https://doi.org/10.1103/PhysRevLett.124.167401}, ArXiv e-print: \url{https://arxiv.org/abs/1903.09105}}
}

% MOOSE/SAM
@TechReport{Zou_2020,
  author      = {Ling Zou and Rui Hu},
  title       = {{SAM code validation on frictional pressure drop through pebble beds}},
  institution = {Argonne National Laboratory},
  day         = 1,
  month       = mar,
  year        = 2020,
  number      = {ANL/NSE-20/5},
  note        = {\url{https://doi.org/10.2172/1608336}}
}

% MOOSE/ERMINE
@Article{Hsu_2020b,
  author  = {Tim Hsu and Jerry H. Mason and Rubayyat Mahbub and William K. Epting and Harry W. Abernathy and Gregory A. Hackett and Anthony D. Rollett and Shawn Litster and Paul A. Salvador},
  title   = {Distributions of local electrochemistry in heterogeneous microstructures of solid oxide fuel cells using high-performance computations},
  journal = {Electrochimica Acta},
  month   = jun,
  year    = 2020,
  volume  = 345,
  pages   = {136191 (16 pages)},
  note    = {\url{https://doi.org/10.1016/j.electacta.2020.136191}}
}

% MOOSE/phase_field
% "The PFM is developed in the open source code MOOSE..."
% This is a "Meeting Abstract" for the Yurkiv_2020 paper, hence the "MA" in the volume number.
% Normally I would list this as an Inproceedings, but since ECS publishes all meeting abstracts
% in a "journal", the Article format is the most natural thing to use here.
@Article{Yurkiv_2020b,
  author  = {Vitaliy Yurkiv and Tara Foroozan and Ajaykrishna Ramasubramanian and Marco Ragone and Reza Shahbazian-Yassar and Farzad Mashayek},
  title   = {{Understanding Zn electrodeposits morphology in secondary batteries using multiscale computational approach}},
  journal = {{ECS} Meeting Abstracts},
  month   = may,
  year    = 2020,
  volume  = {{MA}2020-01},
  number  = 2,
  pages   = {366 (1 page)},
  note    = {\url{https://doi.org/10.1149/MA2020-012366mtgabs}}
}

% MOOSE/phase_field
% "The model is developed in the MOOSE framework..."
@Article{Yurkiv_2020,
  author  = {Vitaliy Yurkiv and Tara Foroozan and Ajaykrishna Ramasubramanian and Marco Ragone and Reza Shahbazian-Yassar and Farzad Mashayek},
  title   = {{Understanding Zn electrodeposits morphology in secondary batteries using phase-field model}},
  journal = {Journal of The Electrochemical Society},
  month   = mar,
  year    = 2020,
  volume  = 167,
  number  = 6,
  pages   = {060503 (11 pages)},
  note    = {\url{https://doi.org/10.1149/1945-7111/ab7e91}}
}

% MOOSE/phase_field
% "The non-dimensional evolution equations were discretized and solved
% using the finite element method, as implemented in the MOOSE framework."
@phdthesis{Kadambi_thesis,
  author = {Sourabh Bhagwan Kadambi},
  school = {North Carolina State University},
  title  = {Interphase boundary segregation engineering},
  note   = {\url{https://repository.lib.ncsu.edu/handle/1840.20/37401}},
  month  = mar,
  year   = 2020
}

% MOOSE/phase_field
% "In this example, the Fe-Cr microstructural evolution using the PF simulation
% in the MOOSE framework [72] is used to demonstrate the approach"
% author:tran Multiscale stochastic reduced-order model for uncertainty propagation
@Misc{Tran_2020,
  author       = {Anh Tran and Jing Sun and Dehao Liu and Tim Wildey and Yan Wang},
  title        = {{Multiscale stochastic reduced-order model for uncertainty propagation using Fokker--Planck equation with microstructure evolution applications}},
  month        = apr,
  year         = 2020,
  howpublished = {ArXiv e-print},
  note         = {\url{https://arxiv.org/abs/2004.06487}}
}

% MOOSE/REDBACK
@Article{Lesueur_2020,
  author  = {Martin Lesueur and Thomas Poulet and Emmanouil Veveakis},
  title   = {{Three-scale multiphysics finite element framework (FE$^3$) modelling fault reactivation}},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = jun,
  year    = 2020,
  volume  = 365,
  pages   = {112988 (37 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2020.112988}, EarthArXiv e-print: \url{https://doi.org/10.31223/osf.io/7h564}}
}

% MOOSE/Zapdos
% This thesis includes simulations from an Applied Materials in-house
% 2D/3D fluid code and also the MOOSE applications ZAPDOS and CRANE"
@phdthesis{DPeterson_thesis,
  author = {David John Peterson},
  school = {North Carolina State University},
  title  = {Characterization of intermediate pressure plasmas with advanced microwave resonator diagnostics},
  note   = {\url{https://repository.lib.ncsu.edu/handle/1840.20/37382}},
  month  = mar,
  year   = 2020
}

% libMesh
% "The continuum model is solved using libMesh, a general-purpose C++ finite-element library."
@Article{Phillips_2020,
  author  = {Caleb M. Phillips and Ernesto A. B. F. Lima and Ryan T. Woodall and Amy Brock and Thomas E. Yankeelov},
  title   = {{A hybrid model of tumor growth and angiogenesis: In silico experiments}},
  journal = {PLOS ONE},
  month   = apr,
  year    = 2020,
  volume  = 15,
  number  = 4,
  pages   = {0231137 (27 pages)},
  note    = {\url{https://doi.org/10.1371/journal.pone.0231137}}
}

% MOOSE/phase_field
% "The finite element software MOOSE ... is applied to implement the outlined model."
@Article{Bai_2020,
  author  = {Yang Bai and Kejie Zhao and Yao Liu and Peter Stein and Bai-Xiang Xu},
  title   = {{A chemo-mechanical grain boundary model and its application to understand the damage of Li-ion battery materials}},
  journal = {Scripta Materialia},
  month   = jul,
  year    = 2020,
  volume  = 183,
  pages   = {45--49},
  note    = {\url{https://doi.org/10.1016/j.scriptamat.2020.03.027}}
}

% IBAMR
% https://engrxiv.org/8ys2k/
% https://www.researchgate.net/publication/331153809_Fluid-Structure_Interaction_Models_of_Bioprosthetic_Heart_Valve_Dynamics_in_an_Experimental_Pulse_Duplicator
@Article{Lee_2020,
  author  = {Jae H. Lee and Alex D. Rygg and Ebrahim M. Kolahdouz and Simone Rossi and Stephen M. Retta and Nandini Duraiswamy and Larry N. Scotten and Brent A. Craven and Boyce E. Griffith},
  title   = {Fluid-structure interaction models of bioprosthetic heart valve dynamics in an experimental pulse duplicator},
  journal = {Annals of Biomedical Engineering},
  month   = may,
  year    = 2020,
  volume  = 48,
  number  = 5,
  pages   = {1475--1490},
  note    = {\url{https://doi.org/10.1007/s10439-020-02466-4}, engrXiv e-print: \url{https://doi.org/10.31224/osf.io/8ys2k}}
}

% MOOSE
% "The body force is subsequently introduced as a source term in Navier-Stokes
% equations solved in MOOSE for the value of fluid velocity."
@Article{Galek_2020,
  author  = {Rafa{\l{}} Ga{\l{}}ek and Joanna Wilk},
  title   = {Numerical simulation of air flow in needle-to-cylinder electrohydrodynamic device},
  journal = {Progress in Computational Fluid Dynamics},
  year    = 2020,
  volume  = 20,
  number  = 2,
  pages   = {84--92},
  note    = {\url{https://doi.org/10.1504/PCFD.2020.106408}}
}

% libMesh
% "The FEM calculations are performed by utilizing the open source LIBMESH library"
@Article{Tan_2020,
  author  = {Ren Kai Tan and Nevin L. Zhang and Wenjing Ye},
  title   = {A deep learning-based method for the design of microstructural materials},
  journal = {Structural and Multidisciplinary Optimization},
  month   = apr,
  year    = 2020,
  volume  = 61,
  number  = 4,
  pages   = {1417--1438},
  note    = {\url{https://doi.org/10.1007/s00158-019-02424-2}}
}

% BISON
% "The structural analysis was performed using the fuel performance modeling code BISON"
@Article{Singh_2020,
  author  = {G. Singh and J. P. Gorton and D. Schappel and B. S. Collins and Y. Katoh and N. R. Brown and B. D. Wirth},
  title   = {{Impact of control blade insertion on the deformation behavior of SiC-SiC channel boxes in BWRs}},
  journal = {Nuclear Engineering and Design},
  month   = jul,
  year    = 2020,
  volume  = 363,
  pages   = {110621 (14 pages)},
  note    = {\url{https://doi.org/10.1016/j.nucengdes.2020.110621}}
}

% MOOSE/BISON
% "The fuel pellet temperature is estimated with the BISON code [28], ..."
@Article{WeiLi_2020,
  author  = {Wei Li and Koroush Shirvan and Shay Harrison and Joseph Pegna},
  title   = {Innovative accident tolerant fuel concept enabled through direct manufacturing technology},
  journal = {Applied Energy},
  month   = apr,
  year    = 2020,
  volume  = 264,
  pages   = {114742 (17 pages)},
  note    = {\url{https://doi.org/10.1016/j.apenergy.2020.114742}}
}

% MOOSE
% "Simulation of restrained ring shrinkage and cracking of
% cementitious materials in a multiphysics simulation framework
% (MOOSE) is discussed in this paper."
@Article{Saklani_2020,
  author  = {Naman Saklani and Zhenhua Wei and Alain Giorla and Benjamin Spencer and Subramaniam Rajan and Gaurav Sant and Narayanan Neithalath},
  title   = {{Finite element simulation of restrained shrinkage cracking of cementitious materials: Considering moisture diffusion, aging viscoelasticity, aleatory uncertainty, and the effects of soft/stiff inclusions}},
  journal = {Finite Elements in Analysis and Design},
  month   = jun,
  year    = 2020,
  volume  = 173,
  pages   = {103390 (13 pages)},
  note    = {\url{https://doi.org/10.1016/j.finel.2020.103390}}
}

% https://www.osti.gov/biblio/1604076-bison-methods-contact-algorithms
@TechReport{Hales_2020,
  author      = {Jason D. Hales},
  title       = {{BISON methods and contact algorithms}},
  institution = {Idaho National Laboratory},
  month       = apr,
  year        = 2020,
  number      = {INL/CON-20-57383},
  note        = {\url{https://tinyurl.com/v73p8c8}}
}

% MOOSE/MARMOT
% "Mesoscale simulations ... were conducted ... in MARMOT"
@InCollection{Tonks_2020,
  author    = {Michael R. Tonks and C. Bhave and X. Wu and Y. Zhang},
  editor    = {Yan Wang and David L. McDowell},
  title     = {Uncertainty quantification of mesoscale models of porous uranium dioxide},
  pages     = {329--354},
  year      = 2020,
  booktitle = {Uncertainty Quantification in Multiscale Materials Modeling, Elsevier Series in Mechanics of Advanced Materials},
  note      = {\url{https://doi.org/10.1016/B978-0-08-102941-1.00010-9}}
}

% "Numerical simulation has been performed with the finite element method in the MOOSE framework..."
@Article{Liu_2020,
  author  = {Yao Liu and Yang-Bin Ma and Wolfram Jaegermann and Ren{\'{e}} Hausbrand and Bai-Xiang Xu},
  title   = {Interface equilibrium modeling of all-solid-state lithium-ion thin film batteries},
  journal = {Journal of Power Sources},
  month   = apr,
  year    = 2020,
  volume  = 454,
  pages   = {227892 (11 pages)},
  note    = {\url{https://doi.org/10.1016/j.jpowsour.2020.227892}}
}

% MOOSE/Rattlesnake
@Article{Prince_2020b,
  author  = {Zachary M. Prince and Jean C. Ragusa},
  title   = {{Space-energy separated representations for multigroup neutron diffusion using proper generalized decompositions}},
  journal = {Annals of Nuclear Energy},
  month   = jul,
  year    = 2020,
  volume  = 142,
  pages   = {107360 (14 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2020.107360}}
}

% MOOSE
@Article{Hsu_2020,
  author  = {Tim Hsu and Rubayyat Mahbub and Jerry H. Mason and William K. Epting and Harry W. Abernathy and Gregory A. Hackett and Anthony D. Rollett and Shawn Litster and Paul A. Salvador},
  title   = {{High Performance Modeling of Heterogeneous SOFC Electrode Microstructures using the MOOSE Framework: ERMINE (Electrochemical Reactions in Microstructural Networks)}},
  journal = {MethodsX},
  month   = feb,
  year    = 2020,
  volume  = 7,
  pages   = {100822 (17 pages)},
  note    = {\url{https://doi.org/10.1016/j.mex.2020.100822}}
}

% MOOSE/navier_stokes
% "The weak form of the Navier-Stokes PDEs is already developed in ...
% MOOSE which was developed by Idaho National Laboratory"
@Article{Alhubail_2020,
  author  = {Mustafa M. Alhubail and Anil Misra and Belladonna Maulianda and Reza Barati},
  title   = {Application of finite element discretization with weak formulation for simulation of acid fracturing in tight carbonate reservoirs},
  journal = {Journal of Petroleum Science and Engineering},
  month   = jul,
  year    = 2020,
  volume  = 190,
  pages   = {107047 (42 pages)},
  note    = {\url{https://doi.org/10.1016/j.petrol.2020.107047}}
}

% "The numerical model is simulated with the multiphysics finite element solver MOOSE"
% https://eartharxiv.org/fqz2x
@Article{Walsh_2020,
  author  = {Stuart D. C. Walsh and Daniel Vogler},
  title   = {Simulating electropulse fracture of granitic rock},
  journal = {International Journal of Rock Mechanics and Mining Sciences},
  month   = apr,
  year    = 2020,
  volume  = 128,
  pages   = {104238 (8 pages)},
  note    = {\url{https://doi.org/10.1016/j.ijrmms.2020.104238}, EarthArXiv e-print: \url{https://doi.org/10.31223/osf.io/fqz2x}}
}

% MOOSE/MARMOT
% "This grain growth model is implemented using the finite element
% method (FEM) and implicit time integration with MARMOT..."
@Article{Cheniour_2020,
  author  = {Amani Cheniour and Michael R. Tonks and Bowen Gong and Tiankai Yao and Lingfeng He and Jason M. Harp and Benjamin Beeler and Yongfeng Zhang and Jie Lian},
  title   = {{Development of a grain growth model for U$_3$Si$_2$ using experimental data, phase field simulation and molecular dynamics}},
  journal = {Journal of Nuclear Materials},
  month   = apr,
  year    = 2020,
  volume  = 532,
  pages   = {152069 (9 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152069}}
}

% MOOSE
% The model is numerically implemented via the finite element method (FEM) within the program
% "NIsoS" developed by authors based on MOOSE framework.
@Article{YYang_2020,
  author  = {Yangyiwei Yang and Patrick K{\"{u}}hn and Min Yi and Herbert Egger and Bai-Xiang Xu},
  title   = {Non-isothermal phase-field modeling of heat--melt--microstructure-coupled processes during powder bed fusion},
  journal = {Journal of the Minerals, Metals, and Materials Society (JOM)},
  month   = apr,
  year    = 2020,
  volume  = 72,
  number  = 4,
  pages   = {1719--1733},
  note    = {\url{https://doi.org/10.1007/s11837-019-03982-y}}
}

% MOOSE
% "A new code, called TIGER, is introduced for modelling coupled thermal-
% hydro processes in porous media."
@Article{Korzani_2020,
  author  = {Maziar Gholami Korzani and Sebastian Held and Thomas Kohl},
  title   = {Numerical based filtering concept for feasibility evaluation and reservoir performance enhancement of hydrothermal doublet systems},
  journal = {Journal of Petroleum Science and Engineering},
  month   = jul,
  year    = 2020,
  volume  = 190,
  pages   = {106803 (34 pages)},
  note    = {\url{https://doi.org/10.1016/j.petrol.2019.106803}}
}

% libMesh repo is used as one of their datasets
@InProceedings{Tu_2020,
  author    = {Huy Tu and Rishabh Agrawal and Tim Menzies},
  title     = {The changing nature of computational science software},
  booktitle = {{Proceedings of the ACM Joint European Software Engineering Conference and Symposium on the Foundations of Software Engineering (ESEC/FSE 2020)}},
  address   = {Sacramento, California},
  month     = nov # {~8--13,},
  year      = 2020,
  note      = {\url{http://ai4se.net/se4cs/docs/githubcs.pdf}}
}

% New MOOSE paper
@Article{Permann_2020,
  author  = {Cody J. Permann and Derek R. Gaston and David Andr{\v{s}} and Robert W. Carlsen and Fande Kong and Alexander D. Lindsay and Jason M. Miller and John W. Peterson and Andrew E. Slaughter and Roy H. Stogner and Richard C. Martineau},
  title   = {{MOOSE: Enabling massively parallel multiphysics simulation}},
  journal = {SoftwareX},
  month   = jan # {--} # jun,
  year    = 2020,
  volume  = 11,
  pages   = {100430 (5 pages)},
  note    = {\url{https://doi.org/10.1016/j.softx.2020.100430}, ArXiv e-print: \url{https://arxiv.org/abs/1911.04488}}
}

% MARMOT/phase_field
% "This model and its derivatives are implemented in the
% implicit FEM phase field code MARMOT..."
@Article{Greenquist_2020b,
  author  = {Ian Greenquist and Michael Tonks and Michael Cooper and David Andersson and Yongfeng Zhang},
  title   = {{Grand potential sintering simulations of doped UO$_2$ accident-tolerant fuel concepts}},
  journal = {Journal of Nuclear Materials},
  month   = apr,
  year    = 2020,
  volume  = 532,
  pages   = {152052 (25 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2020.152052}}
}

% MOOSE/phase_field
% "For two-dimensional simulations, we used mesh adaptivity in the
% open source Multiphysics Object-Oriented Simulation Environment..."
@Article{KKim_2020,
  author  = {Kyoungdoc Kim and Quentin C. Sherman and Larry K. Aagesen and Peter W. Voorhees},
  title   = {{Phase-field model of oxidation: Kinetics}},
  journal = {Physical Review E},
  month   = feb,
  year    = 2020,
  volume  = 101,
  number  = 2,
  pages   = {022802 (16 pages)},
  note    = {\url{https://doi.org/10.1103/PhysRevE.101.022802}}
}

% MOOSE/REDBACK
@Article{Sari_2020,
  author  = {Mustafa Sari and Sotiris Alevizos and Thomas Poulet and Jack Lin and Manolis Veveakis},
  title   = {{A visco-plastic framework for interface processes in sedimentary reservoir rocks at HPHT conditions}},
  journal = {Geomechanics for Energy and the Environment},
  month   = may,
  year    = 2020,
  volume  = 22,
  pages   = {100165 (27 pages)},
  note    = {\url{https://doi.org/10.1016/j.gete.2019.100165}}
}

% MOOSE
% "We present an application, namely the DwarfElephant
% package, to the Multiphysics Object-Orientated Simulation
% Environment (MOOSE) [36], implementing the RB method.
% MOOSE, primarily developed by the Idaho National Laboratory,
% offers a built-in parallelization. The framework builds
% upon the libMesh [23] and PETSc [3] libraries. The RB
% implementation mainly uses the rbOOmit package [24] provided
% by libMesh."
@Article{Degen_2020,
  author  = {Denise Degen and Karen Veroy and Florian Wellman},
  title   = {{Certified Reduced Basis Method in Geosciences: Addressing the challenge of high dimensional problems}},
  journal = {Computational Geosciences},
  month   = feb,
  year    = 2020,
  volume  = 24,
  number  = 1,
  pages   = {241--259},
  note    = {\url{https://doi.org/10.1007/s10596-019-09916-6}, EarthArXiv e-print: \url{https://doi.org/10.31223/osf.io/neh9j}}
}

% MOOSE/Grizzly
% "The overarching goal of this project is to complement ongoing Department of Energy (DOE) Light
% Water Reactor Sustainability (LWRS)-funded Grizzly concrete modeling development efforts by
% providing improved multi-physics models for incorporation into the Grizzly and BlackBear codes."
% https://www.osti.gov/biblio/1599377-multiple-degradation-mechanisms-reinforced-concrete-structures-modeling-risk-analysis
@TechReport{Ballarini_2020,
  author      = {Roberto Ballarini and Bora Gencturk and Amit Jain and Hadi Aryan and Yunping Xi and Mohamed Abdelrahman and Benjamin Spencer},
  title       = {Multiple degradation mechanisms in reinforced concrete structures, modeling and risk analysis},
  institution = {Idaho National Laboratory},
  day         = 13,
  month       = feb,
  year        = 2020,
  number      = {INL/EXT-20-57095},
  note        = {\url{https://doi.org/10.2172/1599377}}
}

% "The algorithms are implemented using libMesh [32] for the finite element assembly..."
@Article{Luo_2020,
  author  = {Li Luo and Lulu Liu and Xiao-Chuan Cai and David E. Keyes},
  title   = {{Fully implicit hybrid two-level domain decomposition algorithms for two-phase flows in porous media on 3D unstructured grids}},
  journal = {Journal of Computational Physics},
  month   = may,
  year    = 2020,
  volume  = 409,
  pages   = {109312 (40 pages)},
  note    = {\url{https://doi.org/10.1016/j.jcp.2020.109312}}
}

@Article{Kong_2020,
  author  = {Fande Kong},
  title   = {{A parallel monolithic multilevel Schwarz preconditioner for the neutron transport criticality calculations with a nonlinear diffusion acceleration method}},
  journal = {Annals of Nuclear Energy},
  month   = jun,
  year    = 2020,
  volume  = 141,
  pages   = {107342 (18 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2020.107342}, ArXiv e-print: \url{https://arxiv.org/abs/1907.12590}}
}

% MOOSE
@Article{Kopanicakova_2020,
  author  = {Alena Kopani{\v{c}}{\'{a}}kov{\'{a}} and Rolf Krause},
  title   = {Recursive multilevel trust region method with application to fully monolithic phase-field models of brittle fracture},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = mar,
  year    = 2020,
  volume  = 360,
  pages   = {112720 (29 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2019.112720}, ArXiv e-print: \url{https://arxiv.org/abs/1903.00379}}
}

% MOOSE/MARMOT/Yellowjacket
@InProceedings{Bajpai_2020,
  author    = {Parikshit Bajpai and Max Poschmann and David Andr{\v{s}} and Chaitanya Bhave and Michael Tonks and Markus Piro},
  title     = {Development of a new thermochemistry solver for multiphysics simulations of nuclear materials},
  booktitle = {TMS 2020 149th Annual Meeting {\&} Exhibition Supplemental Proceedings},
  address   = {San Diego, California},
  pages     = {1013--1025},
  month     = feb # {~23--27,},
  year      = 2020,
  note      = {\url{https://doi.org/10.1007/978-3-030-36296-6_95}}
}

% "Coupling of Thermochimica to various other software packages, such
% as ... the (MOOSE) app Bison ... will also be demonstrated."
@InProceedings{Poschmann_2020,
  author    = {Max Poschmann and Bernard W. N. Fitzpatrick and Srdjan Simunovic and Markus H. A. Piro},
  title     = {{Recent development of Thermochimica for simulations of nuclear materials}},
  booktitle = {TMS 2020 149th Annual Meeting {\&} Exhibition Supplemental Proceedings},
  address   = {San Diego, California},
  pages     = {1003--1012},
  month     = feb # {~23--27,},
  year      = 2020,
  note      = {\url{https://doi.org/10.1007/978-3-030-36296-6_94}}
}

% "The numerical integration of the free energy functional is
% calculated ... and optimized through libMesh"
@Article{PalacioBetancur_2020,
  author  = {Viviana Palacio-Betancur and Julio C. Armas-P{\'{e}}rez and Stiven Villada-Gil and Nicholas L. Abbott and Juan P. Hern\'{a}ndez-Ortiz and Juan J. {de Pablo}},
  title   = {Cuboidal liquid crystal phases under multiaxial geometrical frustration},
  journal = {Soft Matter},
  month   = jan,
  year    = 2020,
  volume  = 16,
  number  = 4,
  pages   = {870--880},
  note    = {\url{https://doi.org/10.1039/C9SM02021G}}
}

% All the simulations are then performed using an original parallel
% Multi-Grid Finite Element flow solver [37], which uses C++ technology
% and libMesh libraries [38].
@Article{Castorrini_2020,
  author  = {Alessio Castorrini and Paolo Venturini and Alessandro Corsini and Franco Rispoli},
  title   = {Simulation of the deposit evolution on a fan blade for tunnel ventilation},
  journal = {Journal of Engineering for Gas Turbines and Power},
  month   = apr,
  year    = 2020,
  volume  = 142,
  number  = 4,
  pages   = {041010 (10 pages)},
  note    = {Paper No.~GTP-19-1438, \url{https://doi.org/10.1115/1.4044930}}
}

% MOOSE/phase_field
@Article{Jokisaari_2020b,
  author  = {A. M. Jokisaari and W. Wu and P. W. Voorhees and J. E. Guyer and J. A. Warren and O. G. Heinonen},
  title   = {Phase field benchmark problems targeting fluid flow and electrochemistry},
  journal = {Computational Materials Science},
  month   = apr,
  year    = 2020,
  volume  = 176,
  pages   = {109548 (12 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2020.109548}}
}

% MOOSE/phase_field
@Article{Jokisaari_2020a,
  author  = {A. M. Jokisaari},
  title   = {{Irradiation-induced internal stresses in polycrystalline $\alpha$-uranium: a mesoscale mechanical approach}},
  journal = {Computational Materials Science},
  month   = apr,
  year    = 2020,
  volume  = 176,
  pages   = {109545 (11 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2020.109545}}
}

% "The LYNX simulator (Lithosphere dYnamic Numerical toolboX) is a MOOSE-based application..."
@Article{Jacquey_2020a,
  author  = {Antoine B. Jacquey and Mauro Cacace},
  title   = {{Multiphysics modeling of a brittle-ductile lithosphere, Part I: Explicit visco-elasto-plastic formulation and its numerical implementation}},
  journal = {Journal of Geophysical Research--Solid Earth},
  month   = jan,
  year    = 2020,
  volume  = 125,
  number  = 1,
  pages   = {e2019JB018474 (21 pages)},
  note    = {\url{https://doi.org/10.1029/2019JB018474}}
}

% "The LYNX simulator (Lithosphere dYnamic Numerical toolboX) is a MOOSE-based application..."
% 19 pages
@Article{Jacquey_2020b,
  author  = {Antoine B. Jacquey and Mauro Cacace},
  title   = {{Multiphysics modeling of a brittle-ductile lithosphere, Part II: Semi-brittle, semi-ductile deformation and damage rheology}},
  journal = {Journal of Geophysical Research--Solid Earth},
  month   = jan,
  year    = 2020,
  volume  = 125,
  number  = 1,
  pages   = {e2019JB018475 (19 pages)},
  note    = {\url{https://doi.org/10.1029/2019JB018475}}
}

% MOOSE
% "The resulting set of equations is implemented in the
% finite-element, multiphysics framework MOOSE..."
@Article{TZhang_2020,
  author  = {Tao Zhang and Marc Kamlah},
  title   = {{Mechanically Coupled Phase-Field Modeling of Microstructure Evolution in Sodium Ion Batteries Particles of Na$_{\text{x}}$FePO$_4$}},
  journal = {Journal of the Electrochemical Society},
  month   = jan,
  year    = 2020,
  volume  = 167,
  number  = 2,
  pages   = {020508 (10 pages)},
  note    = {\url{https://doi.org/10.1149/1945-7111/ab645a}}
}

% MOOSE
% "With comparison to full-order model evaluation with MOOSE..."
@Article{Prince_2020,
  author  = {Zachary M. Prince and Jean C. Ragusa},
  title   = {Application of proper generalized decomposition to multigroup neutron diffusion eigenvalue calculations},
  journal = {Progress in Nuclear Energy},
  month   = mar,
  year    = 2020,
  volume  = 121,
  pages   = {103232 (14 pages)},
  note    = {\url{https://doi.org/10.1016/j.pnucene.2019.103232}}
}

% Rattlesnake
@Article{Schunert_2020,
  author  = {Sebastian Schunert and Adam Zabriskie and Daniel Schwen and Vincent Laboure and Mark DeHart},
  title   = {{Impact of grain size on performance degradation of TREAT LEU}},
  journal = {Annals of Nuclear Energy},
  month   = may,
  year    = 2020,
  volume  = 139,
  pages   = {107294 (7 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2019.107294}}
}

% MOOSE/BISON
% "Thermal contact between the pellet and the cladding was modeled
% using an existing formulation in BISON recommended for LWR analysis."
@Article{Medvedev_2020b,
  author  = {Pavel G. Medvedev and Robert D. Mariani},
  title   = {Conductive inserts to reduce nuclear fuel temperature},
  journal = {Journal of Nuclear Materials},
  month   = apr,
  year    = 2020,
  volume  = 531,
  pages   = {151966 (12 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2019.151966}}
}

% MOOSE
@InProceedings{Madenci_2020,
  author    = {Erdogan Madenci and Deepak Behera},
  title     = {{Inelastic material modeling using weak form of peridynamics within MOOSE framework}},
  booktitle = {{Proceedings of AIAA Scitech 2020 Forum}},
  address   = {Orlando, Florida},
  month     = jan # {~6--10,},
  year      = 2020,
  note      = {\url{https://doi.org/10.2514/6.2020-0965}}
}

% MOOSE/Ferret
% "The phase-field simulations were performed using the FERRET package."
% This is a nature.com journal.
@Article{Tikhonov_2020,
  author  = {{\relax Yu}. Tikhonov and S. Kondovych and J. Mangeri and M. Pavlenko and L. Baudry and A. Sen{\'{e}} and A. Galda and S. Nakhmanson and O. Heinonen and A. Razumnaya and I. Luk'yanchuk and V. M. Vinokur},
  title   = {Controllable skyrmion chirality in ferroelectrics},
  journal = {Scientific Reports},
  month   = may,
  year    = 2020,
  volume  = 10,
  pages   = {8657 (7 pages)},
  note    = {\url{https://doi.org/10.1038/s41598-020-65291-8}, ArXiv e-print: \url{https://arxiv.org/abs/2001.01790}}
}

% MOOSE
@Article{Wilkins_2020b,
  author  = {Andy Wilkins and Benjamin W. Spencer and Amit Jain and Bora Gencturk},
  title   = {A method for smoothing multiple yield functions},
  journal = {International Journal for Numerical Methods in Engineering},
  month   = feb,
  year    = 2020,
  volume  = 121,
  number  = 3,
  pages   = {434--449},
  note    = {\url{https://doi.org/10.1002/nme.6215}}
}

% MOOSE
% "In this work, we adopt the Multiphysics Object-Oriented Simulation Environment
% (MOOSE) [20], an open source C++ math library that provides both parallelism and
% h-adaptivity."
@Article{Goli_2020,
  author  = {E. Goli and N. A. Parikh and M. Yourdkhani and N. G. Hibbard and J. S. Moore and N. R. Sottos and P. H. Geubelle},
  title   = {Frontal polymerization of unidirectional carbon-fiber-reinforced composites},
  journal = {Composites Part A: Applied Science and Manufacturing},
  month   = mar,
  year    = 2020,
  volume  = 130,
  pages   = {105689 (7 pages)},
  note    = {\url{https://doi.org/10.1016/j.compositesa.2019.105689}}
}

% "The finite-element formulation (3.6) is implemented in Multi-Physics Object Oriented Simulation Environment (MOOSE)
@Article{Kim_2020,
  author  = {Tae-Yeon Kim and Wen Jiang and Sungmun Lee and Jeong-Hoon Song and Chan Yeob Yeun and Eun-Jae Park},
  title   = {{A Nitsche-type variational formulation for the shape deformation of a single component vesicle}},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = feb,
  year    = 2020,
  volume  = 359,
  pages   = {112661 (17 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2019.112661}}
}

% MOOSE/BISON
% "Fission gas release modeling performed using BISON fuel performance code"
@Article{Medvedev_2020,
  author  = {Pavel Medvedev},
  title   = {{Effect of diamond additive on the fission gas release in UO$_2$ fuel irradiated to 7.2 GWd/tHM}},
  journal = {Annals of Nuclear Energy},
  month   = may,
  year    = 2020,
  volume  = 139,
  pages   = {107282 (4 pages)},
  note    = {\url{https://doi.org/10.1016/j.anucene.2019.107282}}
}

% MOOSE/phase_field
% "... our simulation was carried out in the Multiphysics
% Object Oriented Simulation Environment (MOOSE) framework."
@Article{Li_2020,
  author  = {Qinan Li and Balachander Gnanasekaran and Yao Fu and G. R. Liu},
  title   = {{Prediction of thermal residual stress and microstructure in direct laser metal deposition via a coupled finite element and multiphase field framework}},
  journal = {Journal of the Minerals, Metals, and Materials Society (JOM)},
  month   = jan,
  year    = 2020,
  volume  = 72,
  number  = 1,
  pages   = {496--508},
  note    = {\url{https://doi.org/10.1007/s11837-019-03922-w}}
}

% MOOSE/BISON
@Article{WJiang_2020,
  author  = {Wen Jiang and Benjamin W. Spencer and John E. Dolbow},
  title   = {{Ceramic nuclear fuel fracture modeling with the Extended Finite Element Method}},
  journal = {Engineering Fracture Mechanics},
  month   = jan,
  year    = 2020,
  volume  = 223,
  pages   = {106713 (29 pages)},
  note    = {\url{https://doi.org/10.1016/j.engfracmech.2019.106713}}
}

% BISON
@Article{Schappel_2020b,
  author  = {D. Schappel and N. R. Brown and K. A. Terrani},
  title   = {{Modeling reactivity insertion experiments of TRISO particles in NSRR using BISON}},
  journal = {Journal of Nuclear Materials},
  month   = mar,
  year    = 2020,
  volume  = 530,
  pages   = {151965 (9 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2019.151965}}
}

% "The phase-field model described in Sec. 3 was implemented in
% the mesoscale fuel performance code MARMOT."
@Article{Hirschhorn_2020,
  author  = {Jacob Hirschhorn and Michael Tonks and Assel Aitkaliyeva and Cynthia Adkins},
  title   = {{Reexamination of a U-Zr diffusion couple experiment using quantitative phase-field modeling and sensitivity analysis}},
  journal = {Journal of Nuclear Materials},
  month   = feb,
  year    = 2020,
  volume  = 529,
  pages   = {151929 (19 pages)},
  note    = {\url{https://doi.org/10.1016/j.jnucmat.2019.151929}}
}

% "The model is solved using MOOSE."
@Article{Wilkins_2020,
  author  = {Andy Wilkins and Qingdong Qu},
  title   = {A formalism to compute permeability changes in anisotropic fractured rocks due to arbitrary deformations},
  journal = {International Journal of Rock Mechanics and Mining Sciences},
  month   = jan,
  year    = 2020,
  volume  = 125,
  pages   = {104159 (17 pages)},
  note    = {\url{https://doi.org/10.1016/j.ijrmms.2019.104159}}
}

% "The numerical simulations are carried out with a finite element (FE)
% open-source application called TIGER ..., which is based on MOOSE"
@Article{Egert_2020,
  author  = {Robert Egert and Maziar Gholami Korzani and Sebastian Held and Thomas Kohl},
  title   = {{Implications on large-scale flow of the fractured EGS reservoir Soultz inferred from hydraulic data and tracer experiments}},
  journal = {Geothermics},
  month   = mar,
  year    = 2020,
  volume  = 84,
  pages   = {101749 (12 pages)},
  note    = {\url{https://doi.org/10.1016/j.geothermics.2019.101749}}
}

% MAMMOTH/BISON
@Article{Gougar_2020,
  author  = {H. D. Gougar and D. A. Petti and P. A. Demkowicz and W. E. Windes and G. Strydom and J. C. Kinsey and J. Ortensi and M. Plummer and W. Skerjanc and R. L. Williamson and R. N. Wright and D. Li and A. Caponiti and M. A. Feltus and T. J. O'Connor},
  title   = {{The US Department of Energy's high temperature reactor research and development program -- Progress as of 2019}},
  journal = {Nuclear Engineering and Design},
  month   = mar,
  year    = 2020,
  volume  = 358,
  pages   = {110397 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.nucengdes.2019.110397}}
}

% BISON
% "BISON showed agreement with German data for Ag, Cs, and Sr release from TRISO fuel."
@Article{Schappel_2020,
  author  = {D. Schappel and K. Terrani and L. L. Snead and B. D. Wirth},
  title   = {{Modeling radionuclide release of TRISO bearing fuel compacts during post-irradiation annealing tests}},
  journal = {Nuclear Engineering and Design},
  month   = feb,
  year    = 2020,
  volume  = 357,
  pages   = {110428 (18 pages)},
  note    = {\url{https://doi.org/10.1016/j.nucengdes.2019.110428}}
}

% BISON is used as an input to the method.
@Article{Radaideh_2020,
  author  = {Majdi I. Radaideh and Tomasz Kozlowski},
  title   = {{Surrogate modeling of advanced computer simulations using Deep Gaussian Processes}},
  journal = {Reliability Engineering \& System Safety},
  month   = mar,
  year    = 2020,
  volume  = 195,
  pages   = {106731 (16 pages)},
  note    = {\url{https://doi.org/10.1016/j.ress.2019.106731}}
}

% "... we implement these phenomena as numerical models for 2D simulations in libMesh..."
@Article{Grave_2020,
  author  = {M. Grave and Jos{\'{e}} J. Camata and Alvaro L. G. A. Coutinho},
  title   = {{Residual-based variational multiscale 2D simulation of sediment transport with morphological changes}},
  journal = {Computers \& Fluids},
  month   = jan,
  year    = 2020,
  volume  = 196,
  pages   = {104312 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.compfluid.2019.104312}}
}

% MOOSE
% "The simulator is an application developed based on the MOOSE framework..."
% https://pangea.stanford.edu/ERE/db/WGC/papers/WGC/2020/11037.pdf
@InProceedings{Wang_2020,
  author    = {Jia Wang and Fabian Nitschke and Emmanuel Gaucher and Thomas Kohl},
  title     = {{Numerical simulation of temperature logs in high temperature wells: Towards the application to the RN-15/IDDP2 well}},
  booktitle = {{In Proceedings of World Geothermal Congress}},
  address   = {Reykjavik, Iceland},
  month     = apr # {~26--} # may # {~2,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/yygek73o}}
}

% IBAMR/libMesh
@Article{Kolahdouz_2020,
  author  = {Ebrahim M. Kolahdouz and Amneet Pal Singh Bhalla and Brent A. Craven and Boyce E. Griffith},
  title   = {An immersed interface method for discrete surfaces},
  journal = {Journal of Computational Physics},
  month   = jan,
  year    = 2020,
  volume  = 400,
  pages   = {108854 (37 pages)},
  note    = {\url{https://doi.org/10.1016/j.jcp.2019.07.052}, ArXiv e-print: \url{https://arxiv.org/abs/1812.06840}}
}

% "The simulations were performed using MOOSE framework [42]."
@Article{Ke_2020,
  author  = {H. Ke and A. {Garcia Jimenez} and D. A. {Rodrigues Da Silva} and I. Mastorakos},
  title   = {Multiscale modeling of copper and copper/nickel nanofoams under compression},
  journal = {Computational Materials Science},
  month   = feb,
  year    = 2020,
  volume  = 172,
  pages   = {109290 (8 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2019.109290}}
}

% MOOSE
@Article{Greenquist_2020,
  author  = {Ian Greenquist and Michael R. Tonks and Larry K. Aagesen and Yongfeng Zhang},
  title   = {Development of a microstructural grand potential-based sintering model},
  journal = {Computational Materials Science},
  month   = feb,
  year    = 2020,
  volume  = 172,
  pages   = {109288 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.commatsci.2019.109288}}
}

% MOOSE
% "The model was developed using the finite element method with the
% open source Multiphysics Object-Oriented Simulation Environment (MOOSE)"
@Article{Zhang_2020,
  author  = {Shuaifang Zhang and Wen Jiang and Michael R. Tonks},
  title   = {A new phase field fracture model for brittle materials that accounts for elastic anisotropy},
  journal = {Computer Methods in Applied Mechanics and Engineering},
  month   = jan,
  year    = 2020,
  volume  = 358,
  pages   = {112643 (15 pages)},
  note    = {\url{https://doi.org/10.1016/j.cma.2019.112643}}
}

% MOOSE
% "Equations 1-5 are solved using the Multiphysics Object Oriented Simulation Environment (MOOSE)"
% https://pangea.stanford.edu/ERE/db/WGC/papers/WGC/2020/22046.pdf
@InProceedings{Birdsell_2020,
  author    = {Daniel T. Birdsell and Martin O. Saar},
  title     = {{Modeling ground surface deformation at the Swiss HEATSTORE underground thermal energy storage sites}},
  booktitle = {{In Proceedings of World Geothermal Congress}},
  address   = {Reykjavik, Iceland},
  month     = apr # {~26--} # may # {~2,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/w2et9t3}}
}

% MOOSE
% "The numerical model uses the Multiphysics Object Oriented Simulation Environment..."
% https://www.researchgate.net/publication/335060485_HEATSTORE_SWITZERLAND_New_Opportunities_of_Geothermal_District_Heating_Network_Sustainable_Growth_by_High_Temperature_Aquifer_Thermal_Energy_Storage_Development
@InProceedings{Guglielmetti_2020,
  author    = {Luca Guglielmetti and others},
  title     = {{HEATSTORE SWITZERLAND: New opportunities of geothermal district heating network sustainable growth by high temperature aquifer thermal energy storage development}},
  booktitle = {{In Proceedings of World Geothermal Congress}},
  address   = {Reykjavik, Iceland},
  month     = apr # {~26--} # may # {~2,},
  year      = 2020,
  note      = {\url{https://tinyurl.com/yypw4dkq}}
}
